A three-dimensional nanofibrous scaffold for cartilage tissue engineering using human mesenchymal stem cells
A three-dimensional nanofibrous scaffold for cartilage tissue engineering using human mesenchymal stem cells
Wan-Ju Li, Richard Tuli, Chukwuka Okafor, Assia Derfoul, Keith G. Danielson, David J. Hall, Rocky S. Tuan
Summary:
A stem cell is an undifferentiated cell of a multi-cellular organism that has the ability to differentiate into a range of specialized cell types. Adult stem cells are those that are found throughout the body after embryonic development, whereas embryonic stem cells are found in an early-stage embryo. Tissue engineers are interested in adult stem cells because of their multidifferentiative potential of generating several cell types. In this paper, a 3-dimensional nanofibrous scaffold (NFS) was created for cartilage tissue engineering with the use of adult mesenchymal stem cells (MSCs). These cells give rise to chondrocytes, cells that secrete the matrix of cartilage and become embedded in it, as long as the cells are maintained in culture and treated with the transforming growth factor-b (TGF-b). The premise of the experiment is to show that NFS is a more biologically representative method to model cartilage repair than the cell pellet method mentioned below. An in vitro analysis of chondrogenesis was conducted in NFSs with MSCs placed into the scaffold. In order to conduct the experiment, first MSCs were isolated and grown. MSCs were isolated from bone marrow of the femoral neck and grown in a DMEM/bovine serum mixture. Next, 3-dimensional cell pellet cultures and NFSs were created. The cell pellet was formed by placing 250,000 cells in a conical vial, centrifuging the solution and letting the sample sit over night. The NFSs were formed by electrospinning a polymer that resembles an in vivo natural extracellular matrix (Figure 1, A & B). In order to induce chondrogenesis, the cells were supplied with the transforming growth factor and incubated for 21 days. Four samples were analyzed, 2 CP samples (one with TGF-b, one without) and 2 NFS samples (one with TGF-b, one without). Subsequently RNA extraction was performed, followed by RT-PCR for 32 cycles (Figure 3). A sulfated glycosaminoglycan (sGAG) assay was performed to measure the biosynthetic rate of the cells and based on the extracts of the sGAG assay (Figure 4), a cell proliferation assay was conducted to estimate MSC proliferation. Finally, after 21 days of harvesting an immunohistological analysis of CP and NFS was conducted by washing with PBS, staining with a Broad Spectrum Histostain-SP kit and counterstaining with hematoxylin (Figure 6 & 7).
The major goal of the experiment was to compare induced chondrogenesis in a CP culture compared to a 3-dimensional scaffold (NFS). Although the CP method of chondrogenesis is one of the more typical methods used in research, this paper proposes that the NFS method more accurately describes the in vivo setting in the human body. Furthermore, according to figure 2 in the paper, CP produces unorganized collagen-like fibers, whereas NFS cultures showed a smooth, even surface (more biologically representative of the body). Microscopic images were taken of the two techniques to show the cartilage-like tissue growth when TGF-b was present. The NFS model shows zonal architecture similar to native cartilage. According to the literature, this occurs because of increased ECM production in a 3-dimensional setting as opposed to the CP method. In conclusion, the NFS method provides a more realistic comparison to in vivo situations and more appropriately models a tissue engineering-based cartilage repair technique.
Critique:
Overall, the scaffold method seems to be a definite improvement in terms of biological representation for cartilage repair. As we talked about in lecture, a 3-D model more accurately describes an in vivo environment. The NFS method does not require centrifugation and therefore, may more accurately describe cells than cells that were forced into a pellet. The NFS method tries to alleviate this concern by mimicking the 3-dimensional nature of cartilage repair in the body. Furthermore, this method allows the cells to have a high surface area to volume ratio instead of being densely packed into a pellet. The CP culture induces cell-cell interactions, and this action is a necessity to chondrogenesis initiation. The growth seen in the CP , therefore, cannot completely be accredited to the pellet method, and as a result the CP method may be less accurate than NFS. Although a quantitative biochemical assay tells us that the NFS method is equivalent and “sometimes” higher than the CP method, the microstructure resemblance between the 3-dimensional method and an accurate biological description of cartilage growth is very similar (comparison of zonal architecture is accurate) to an in vivo situation. Although the overall methodology behind the proposed scaffold idea seemed to be accurate, it would have been useful to show a comparison between hydrogel and non-hydrogel polymer scaffolds, in order to ensure that the scaffold material did not have a major affect on the cell growth seen. In future works it will be useful to include this data, as well as an image that shows in vivo cartilage repair in comparison to the scaffold method described above.
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13 comments:
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is there any work or comments about the modulus of the scaffold? such as stiffness, porosity etc. how does the material modulus different from/similar to the natural cartilage? what would be the effects of difference/similarity in differentiation?
For the NFSs what was the polymer used to electrospin the original matrix? Does this matrix become degraded by the MSCs and replaced with collagen?
You say that cell-cell interactions are necessary for chondrogenesis in the CP method, but then say that the growth isn't fully attributed to the CP method. Doesn't the CP method facilitate cell-cell interactions by pelleting all the cells together? You also say that ECM production is increased 3x in a 3D structure compared to in the CP method, but aren't the cells in the pellet in a "3D structure"?
How are the cells seeded onto the NFS in the first place? Specifically, were they placed on the surface, or inside of the graft? With the cell pellet method, the cell density is uniform, but with a fibrous scaffold in the way, isn't it more difficult to ensure a minimum level of cells throughout the graft?
Do you know how TGF-b works to induce chondrogenesis and/or promote cartilage-like tissue formation?
I'm also curious as to what material is used to fabricate the NSF and how, or if, that material affects the cells.
Also, how thick is the NSF and are the cells seeded throughout the material or on the surface? If they're embedded into the polymer, do the cells farther in the scaffold (farther away from the surface) receive sufficient nutrients and exposure to TGF-b? How long can the cells grow and remain relatively content in the NSF?
I am confused on the CP method. so you mentioned the CP method fulfill the interaction requirement for chondrocyte development. but does the pelleting of cell only increases cell density in solution, which means I can just add more of the cells to achieve the same effect?
Once cells are seeded in the NFS, how are they supplied with nutrients/how are wastes disposed of? Is the NFS placed within a dish of media or is a bioreactor involved that flows media by the cells? I am curious because some studies indicate that fluid flow contributes the extracellular environment and therefore has an affect on the differentiation of stem cells, but this study seems to suggest that the composition of the matrix is a more important determining factor.
Since both NFS and CP display a 3D construction, the argument that NFS provides a more identical environment to in vivo conditions does not seem that valid. Perhaps, the fabrication of the NFS is more similar to the matrix of the chondrocytes in vivo, which can lead to increased chondrogenesis. For example, you mention that the surface to volume ratio of the NFS is much greater than the densely packed CP, which can be a characteristic of the in vivo environment that results in chondrocyte differentiation/proliferation.
It has been shown that TGF-b levels in blood increase as people age, resulting in the activation of pathways that inhibit healthy differentiation of stem cells. Do you think it might be useful to repeat the same experiment with different concentrations of TGF-b to test the effect of changing TGF-b on the differentiation of these cells in NFSs? Do you imagine the differentiation would still occur in TGF-b levels representative of those present in the blood in mature humans?
I understand that the NFS is made from hydrogel. Hydrogels also contain a lot of water. Is there an issue of these NFS, because of their size, degrading readily? What happens to them after implantation over time?
There aren't any comments on the modulus of the scaffold, stiffness, porosity, or a strict comparison to natural cartilage. All the paper says is that the zonal architecture is "reminiscent of the superficial, middle, and deep zones of native articular cartilage." These comments would be great for future works.
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