Cartilage Repair Using Human Umbilical Cord Blood-Derived Mesenchymal Stem Cells Embedded in Hyaluronic Acid Hydrogel in a Minipig Model


Cartilage shows lousy regenerative capabilities. Fortunately, it is possible to regenerate cartilage with human umbilical cord blood-derived mesenchymal stem cells (hUCB-MSCs) that have been embedded in a hyaluronic acid (HA) hydrogel composite. In fact, such a combination has shown remarkable results in rat and rabbit models.

In this present study, published in Stem Cells Translational Medicine, Yong-Geun Park and his colleagues from SungKyunKwan University School of Medicine, in Seoul, South Korea sought to confirm the efficacy of this protocol in a in a pig model using three different hUCB-MSC cell lines.

Park and his coworkers generated full-thickness cartilage injuries in the trochlear groove of each knee in 6 minipigs. Three weeks later, an even larger cartilage defect, 5 mm wide by 10 mm deep, was created, followed by an 8-mm-wide and 5-mm-deep boring. In short, the knee cartilages of these minipigs were very messed up.

Trochlear-groove

To these knee cartilages, a mixture (1.5 ml) of hUCB-MSCs (0.5 × 107 cells per milliliter) and 4% HA hydrogel composite were troweled into was then cartilage defects of the right knee. The left knee served as an untreated control. Each cell line was used in two minipigs.

Macroscopic findings of the osteochondral defects of the porcine knees. At 12 weeks postoperatively, the defects of both knees had produced regenerated tissues that were pearly white and firm. These new tissues, which resembled articular cartilage, appeared adherent to the adjacent cartilage and had restored the contour of the femoral condyles (smooth articular surfacewithout depression). The regenerated tissue of the control knee (left knee) looked fibrillated. Grossly, no differencewas seen in the quality of the repaired tissue in the transplanted knee (right knee) among the three groups with different cell lines. (A): Group A. (B): Group B. (C): Group C. Abbreviations: HA, hyaluronic acid; hUCB-MSCs, human umbilical cord blood-derived mesenchymal stem cells.
Macroscopic findings of the osteochondral defects of the porcine knees. At 12 weeks postoperatively, the defects of both
knees had produced regenerated tissues that were pearly white and firm. These new tissues, which resembled articular cartilage, appeared adherent to the adjacent cartilage and had restored the contour of the femoral condyles (smooth articular surface without depression). The regenerated tissue of the control knee (left knee) looked fibrillated. Grossly, no difference was seen in the quality of the repaired tissue in the transplanted knee (right knee) among the three groups with different cell lines. (A): Group A. (B): Group B. (C): Group C. Abbreviations: HA, hyaluronic acid; hUCB-MSCs, human umbilical cord blood-derived mesenchymal stem cells.

12 weeks after surgery, the pigs were sacrificed, and the degree of subsequent cartilage regeneration was evaluated by gross and more detailed microscopic analysis of the knee tissue. The transplanted knee showed superior and more complete joint-specific (hyaline) cartilage regeneration compared with the control knee. The microscopic characteristics of the knee cartilage showed that those animals that received the hUCB-MSCs had greater rates of cell proliferation and cells that differentiated into cartilage-making cells.

Microscopic findings of the regenerating osteochondral defects on porcine articular cartilage (safranin O and fast green staining). At 12 weeks postoperatively, the surface of the repairing tissue in the control knee (left knee) was poorly stained for glycosaminoglycan. In the transplanted knee (right knee), both the regenerated tissue and the adjacent cartilage to which it had become adherent exhibited the normal orthochromatic staining properties with safranin O. (A): Group A. (B): Group B. (C): Group C. Scale bars = 2 mm. Abbreviations: HA, hyaluronic acid; hUCB-MSCs, human umbilical cord blood-derived mesenchymal stem cells.
Microscopic findings of the regenerating osteochondral defects on porcine articular cartilage (safranin O and fast green staining). At 12 weeks postoperatively, the surface of the repairing tissue in the control knee (left knee) was poorly stained for glycosaminoglycan. In the transplanted knee (right knee), both the regenerated tissue and the adjacent cartilage to which it had become adherent exhibited the normal orthochromatic staining properties with safranin O. (A): Group A. (B): Group B. (C): Group C. Scale bars = 2 mm. Abbreviations: HA, hyaluronic acid; hUCB-MSCs, human umbilical cord blood-derived mesenchymal stem cells.

These data show consistent cartilage regeneration using composites of hUCB-MSCs and HA hydrogel in a large animal model. These experiments could be a stepping stone to a human clinical trial in the future that treats osteoarthritis of the knees with hUCB-MSCs embedded in HA hydrogel.

Converting Immune Cell into Another Type of Immune Cell


What does it take to directly convert an antibody-producing B cell into a scavenging macrophage? The answer: one gene, according to a report in the July 30th issue of Stem Cell Reports. This directly reprogramming is transformation is possible because a transcription factor called C/EBPa can short-circuit the cells so that they re-express genes reserved for embryonic development.

Over the past 65 years, research teams in laboratories all over the world have shown that many different types of specialized cell types can be forcibly reprogrammed into another, but how this occurs is only recently been realized. These “transdifferentiations,” as they’re called, include reprogramming a skin cell into a muscle cell, or a muscle cell into a brown fat cell with the addition of just one or two transcription factors that bind to a cell’s DNA and induce the expression of other genes.

“For a long time it was unclear whether forcing cell fate decisions by expressing transcription factors in the wrong cell type could teach us something about what happens normally during physiological differentiation,” said senior study author Thomas Graf, Ph.D., group leader at the Centre for Genomic Regulation in Spain. “What we have now found is that the two processes are actually surprisingly similar.”

According to lead author of this study, Chris van Oevelen, Ph.D., B cell transdifferentiation occurs when C/EBPa binds to two regions of DNA that act as gene expression enhancers. One of these regions is typically active in immune cells, but the other is only activated when macrophage precursors are ready to differentiate. Thus, the synergism of these two enhancer pathways can cause the B cell to act like a macrophage precursor, which triggers B cell-to-macrophage transdifferentiation.

“This has taught us a great deal about how a transcription factor can activate a new gene expression program (in our case, that of macrophages) but has left us in the dark about the other part of the equation; namely, how the factor silences the B cell program, something that must happen if transdifferentiation is to work,” Dr. Graf said. “This is one of the questions we are focusing on now.”

Dr. Graf is interested in this pathway because of its potential therapeutic applications. As it turns out, C/EBPa-induced B cell-to-macrophage transdifferentiation can convert both human B cell lymphoma or leukemia cells into functional, non-cancerous macrophages. Graf believes that induced transdifferentiation could become therapeutically relevant if drug researchers can find a molecule that can replace C/EBPa. Additionally, understanding the mechanisms of this process would help labs worldwide who use transdifferentiation approach to generate cells for regenerative purposes.