Engineering and analysis of load bearing tissues with heterogeneous cell populations are still a challenge. Here, we describe a method for creating bi-layered alginate hydrogel discs as a platform for co-culture of diverse cell populations within one construct.
Many load bearing tissues possess structurally and functionally distinct regions, typically accompanied by different cell phenotypes with differential mechanosensing characteristics. Engineering and analysis of these tissue types remain a challenge. Layered hydrogel constructs provide an opportunity for investigating the interactions among multiple cell populations within single constructs. Alginate hydrogels are both biocompatible and allow for easy isolation of cells after experimentation. Here, we describe a method for the development of small sized dual layered alginate hydrogel discs. This process maintains high cell viability of human mesenchymal stem cells during the formation process and these layered discs can withstand unconfined cyclic compression, commonly used for stimulation of hMSCs undergoing chondrogenesis. These layered constructs can potentially be scaled up to include additional levels, and also be used to segregate cell populations initially after layering. This dual layer alginate hydrogel culture platform can be used for many different applications including engineering and analysis of cells of load bearing tissues and co-cultures of other cell types.
Compressive load bearing tissues such as articular cartilage or intervertebral discs consist of heterogeneous tissue regions that are critical for both biomechanical function and appropriate mechano-transduction in the tissue. Not only is cellular organization and function distinct in different regions, but the extracellular matrices (ECM) are also varied in composition and organization. For example, articular cartilage consists of three primary zones with varying cell morphology, mechanical function, and ECM. Differences in their ECM lead to differential load bearing responsibilities; the superficial layer is primarily involved in tensile response to load, while the middle and deep zones are mainly accountable for response to compression 1. Similarly, in the intervertebral disc, a gel-like nucleus pulposus is surrounded by a lamellar annulus fibrosis and the cells within these two distinct areas experience different types of biophysical stimuli 2. In these types of tissues, cells and the extracellular matrices within the tissue layers interact with each other as the tissue undergoes and responds to mechanical forces.
Recapitulation of such heterogeneous tissue structures remains a challenge in tissue engineering and regenerative medicine, and our understanding of their biological significance is limited. There is a need for culturing platforms for analyzing stratified tissues as well as co-cultures of different populations of cells within one construct. In articular cartilage tissue engineering, scaffold-less layered constructs have been constructed by harnessing the ability of zonal chondrocytes to deposit varied ECM to mimic the different layers of this tissue 3,4. However, layered hydrogel constructs provide an opportunity for investigating the interaction of diverse types of cell populations that lack the ability to form a robust tissue independently. For example, different populations of mesenchymal stem cells can be co-cultured within layered constructs. Such layered scaffolds have been used with both chondrocytes and differentiating mesenchymal stem cells for improved tissue engineering 5. Not only can different cell populations be co-cultured in similar hydrogel layers, but a single cell type can also be cultured within layers that have been manipulated to have varying stiffness or biochemical content to elicit different responses from cells 6,7.
Many different biomaterial hydrogels have been used to layer cell populations for cartilage tissue engineering such as those using polyethylene glycol or poly vinyl alcohol bases 7-9. However, alginate hydrogels are one of the simplest biomaterials from which to create layered scaffolds for studying heterogeneous cell populations in co-culture. While agarose hydrogels are also easily formed, alginate hydrogels have the added benefit of allowing easy isolation of cells from the 3-D construct for analysis of individual cells as has been described previously 10. In previous studies, bi-layered alginate hydrogels have been formed in thin sheets and from these sheets, sections were sliced (e.g., using a biopsy punch) for particular applications such as for analysis of biochemical content or interfacial shear properties 11,12. Another method for forming thin alginate sheets has been described with the potential for stratification into multiple layers, but still would require alteration to the hydrogel for use in mechanical testing 13.
Here, we present a method for reproducibly creating bi-layered alginate hydrogel discs for use in co-culturing different populations of cells. This alginate disc platform possesses several advantages. Primarily, the reproducible shape and small size is conducive for mechanical stimulation of the embedded cells without requiring a biopsy punch or other physical alteration to the hydrogel for many applications. Additionally, cell viability remains high during the layering process, and after gel formation a clear separation of the two cell populations within the gel is visible with no initial overlapping region.
1. Preparation for Formation of Alginate Discs
2. Formation of Cell Seeded Alginate Discs
3. Layering of Alginate Discs
Figure 1 depicts the formation and layering of the alginate hydrogels. Completed bi-layered gels exhibit a complete initial separation of cell populations as shown in Figure 2. Cell viability of human mesenchymal stem cells) embedded within these hydrogels and layered remains high and comparable to the bulk hydrogels as shown in Figure 3. Viability was assessed after annealing, slicing the gels vertically to access the center and then staining the live cells in the annealed gels with a live cell tracker, CMFDA (green) and the dead cells (red) with Ethidium homodimer-1 using the manufacturer's instructions. Confocal Z-stacks were taken of the cut surface using a fluorescence microscope approximately 100 µm into the gel. These images were projected into one 2D image. Live and dead cells were then quantified using the particle analyzer feature in the ImageJ software.
We wanted to verify that these layered hydrogels, lacking cells, would be able to withstand cyclic compression, similar to that needed to induce a chondrogenic response. We found that the hydrogels do remain intact after seven days in culture and subsequent unconfined cyclic compression for 4 hr at 1 Hz from 0 – 10% strain. However, after isolating the peak stress from each cycle and analyzing the trends over the four-hour stimulation, the trends indicate that the layered hydrogels have a different response to the cyclic compression compared to the bulk, non-layered, hydrogels. Cyclic compression over four hours resulted in significantly different (p = 0.03) peak stress trends between layered and non-layered gels (Figure 4). Statistics were completed using the Student's T-test (alpha = 0.05).
Figure 1: Schematic of Layered Hydrogel Formation. A. Image of the stacked mold for the addition of 2% alginate + cell mixture with a depiction of the stacking order for the bottom and top mold halves. B. Schematic depicting procedure for layering of the gel. Please click here to view a larger version of this figure.
Figure 2: Representative Separation of Cell Populations in Layered Hydrogel. Model cell line 293FT HEK cells were either stained with live cell tracker CMFDA (green) or CMTPX (red). Each of these cell groups were embedded in 2% (w/v) alginate discs, and then halves of these discs were layered together. A piece was cut from the CMTPX side to identify it during imaging. Scale bar = 100 µm. Please click here to view a larger version of this figure.
Figure 3: High Cell Viability within Layered Hydrogel after Layering Process is Complete. Human mesenchymal stem cells embedded in bulk and bi-layered hydrogels were stained with live cell (green) tracker CMFDA and dead cells (red) were stained with Ethidium homodimer-1. Viability remained high for both hydrogel groups after the layering process. Scale bar = 100 µm. Please click here to view a larger version of this figure.
Figure 4: Significantly Different Trends of Layered Hydrogel Cyclic Compression Response to Cyclic Compression. Hydrogels were incubated in a cell culture incubator for seven days and subsequently subjected to 0 – 10% unconfined cyclic compression for four hours at 1 Hz. Peak stresses (± SEM) for each cycle were isolated and the trends over the loading period analyzed. Trends under unconfined cyclic compression from 0 – 10% strain for layered (n = 9) and bulk (n = 8) gels are significantly different (p = 0.03). Please click here to view a larger version of this figure.
Here, we describe a protocol for the formation of layered alginate hydrogel discs for studying co-cultures of multiple cell populations, such as those in physiologically layered tissues, e.g., cartilage. Layered structures, such as the described culture platform, can be used to examine the interplay between two distinct cell populations subjected to the same culture environment or under load.
Alginate is an anionic linear polysaccharide that has been found to be biocompatible and has been successfully used for cartilage biology and tissue engineering research 12,14. Alginate hydrogels are formed using divalent cations for crosslinking, e.g., calcium ions. These crosslinks can be undone by removing the cations using a chelator, such as sodium citrate or EDTA, and this process has been used previously to isolate chondrocytes that have been cultured in the gels 3,4,12. Similarly, the same principle has also been successfully applied for adhering alginate sheets in bilayers or even clusters of alginate beads together 11,12,15. The platform described here relies on this same process, but is used to form small disc-shaped layered hydrogels. This is a two-step process in which first, alginate discs are formed using molds submerged in a calcium-rich bath. These are then sliced in half and treated with a calcium chelating solution to locally release the calcium ions from the crosslinked alginate. By placing these treated surfaces together and re-immersing the discs in a calcium-rich solution, crosslinks are reformed, making bi-layered constructs. These small layered gels eliminate the need for biopsy punches to generate easy-to-culture samples compatible with assays and experiments such as mechanical testing, as shown in Figure 4, thereby minimizing waste of oftentimes precious cells as well as fabrication materials.
As shown in Figure 3, this process of forming and layering the hydrogels resulted in similarly high viability as the control or bulk hydrogels indicating that this procedure is not overly taxing to the cell population despite the length and absence of replenishing nutrients. The lack of an initial overlapping region in the gel allows physical separation during initial co-culture and the ability to observe changes to that interface over time. Studies have shown that over long culture periods this interface may lose definition due to cellular cross-infiltration and extracellular matrix deposition 11. While the initial layered disc does not contain any adhesion molecules, as extracellular matrix is deposited, there is also a potential for investigating the merging of cell populations and the changing interface between the layers.
These bi-layered discs can be used easily for dynamic compression stimulation. We were able to confirm that these hydrogels withstand dynamic compression without separation of the halves. However, during this process, peak load exhibited by the layered hydrogels during the four-hour cyclic compression were found to be significantly different from the non-layered, bulk, hydrogels. This result suggests complex, non-linear strain transfer between the layers and reveals a need for a physically layered control gel, e.g., bi-layered hydrogel with the same cell population/condition in each layer, an important detail to note when planning the experimental design for studies involving mechanical loading. Better understanding of the observed differences could be achieved through computational modeling of spatial mechanics within these gels. Not only would such analyses help clarify the strain distribution and transfer between the layers, but it would also be instrumental for interpreting cellular behavior in these layered gels, especially with layers of varying mechanical properties.
This is a versatile culture system that can be used for physical separation of cell populations during co-culture as described. Additionally, it can also be used as a base structure for further development. Changes to the existing structure could include increasing the number of layers, changing the sizes or the relative stiffness of the layers, and incorporating additional extracellular matrix components into one or more of the layers. However, these expansions will require careful evaluation. In addition to changes in the distribution of forces throughout the discs, increasing the size and number of layers could lead to decreases in cell viability in the center of the gels and physical instability during mechanical stimulation. Further, large additions of extracellular matrix and stimulating proteins or alterations to the alginate to provide adhesion moieties may interfere with gel formation and annealing processes.
This culture platform was developed for research applications for investigating the relationships between different cell populations in 3D culture. Thus, it is limited by its lack of scalability for clinical applications. Alternative methods for creating layered hydrogels, such as 3D printing, may ultimately be more clinically relevant due to anticipated future scalability advances, control over microstructure in the disc interior, and customizability of macroscale geometric features. For research applications, as presented here, the alginate discs do not independently provide adhesion moieties for cells, which could limit its application to other cells types. The comparable alternative to alginate when considering ease of use is agarose, which suffers from similar limitations. Further, it requires the use of enzymes to release cells for downstream analysis, while alginate crosslinks can be safely removed using calcium chelating agents. Primarily, this culture platform will help with improving the understanding of relationships between cell populations in hydrogels and potentially the effects of mechanical stimulation of these co-cultures. This understanding will then inform the development of therapies for heterogeneous tissues, especially loading bearing tissues such as articular cartilage or intervertebral discs.
The authors have nothing to disclose.
This work was funded by the National Science Foundation (CBET 0845754, AHH).
Alginic Acid sodium salt | Sigma Aldrich | A1112 | Solution made in wt% using DPBS (-/-) |
1x Dulbecco's Phosphate Buffered Saline (-/-) | Gibco Life Technologies | 14190 | |
1x Dulbecco's Phosphate Buffered Saline (+/+) | Gibco Life Technologies | 14190 | |
Dulbecco's Modified Eagle Medium | Gibco Life Technologies | 11965 | Example. Use desired medium type |
Syringe Filters (0.02um Nylon) | FisherBrand | 0979C | |
Calcium Chloride Dihydrate | Fisher Bioreagents | BP510 | Prepare solution in sterile water |
Criterion Blotter Filter Paper | Biorad | 1704085 | Cut to size of endplates for mold formation |
Cell Microsieve Membrane (10um pore size) | Biodesign Inc of New York | N10R | Cut to size of endplates for mold formation |
0.25% Trypsin-EDTA (1x), phenol red | Gibco Life Technologies | 25200 | Thaw in 37ᵒC water bath |
Sodium citrate dihydrate | FisherScience | S93364 | |
Ethylenediaminetetraacetic acid tetrasodium salt dihydrate (EDTA) | FisherBioreagent | BP121 | |
Fetal Bovine Serum | Gibco Life Technologies | 26140 | Used in example mesenchymal stem cell basal growth media |
Penicilin/Streptomycin (10000 U/ml) | Gibco Life Technologies | 15140 | Used in example mesenchymal stem cell basal growth media |
L-Glutamine (200mM) | Gibco Life Technologies | 25030081 | Used in example mesenchymal stem cell basal growth media |
Non-essential Amino Acids (100x) | Gibco Life Technologies | 11140050 | Used in example mesenchymal stem cell basal growth media |