This article will focus on developing polymer coated surfaces for long-term, stable culture of stem cell derived human hepatocytes.
Currently, one of the major limitations in cell biology is maintaining differentiated cell phenotype. Biological matrices are commonly used for culturing and maintaining primary and pluripotent stem cell derived hepatocytes. While biological matrices are useful, they permit short term culture of hepatocytes, limiting their widespread application. We have attempted to overcome the limitations using a synthetic polymer coating. Polymers represent one of the broadest classes of biomaterials and possess a wide range of mechanical, physical and chemical properties, which can be fine-tuned for purpose. Importantly, such materials can be scaled to quality assured standards and display batch-to-batch consistency. This is essential if cells are to be expanded for high through-put screening in the pharmaceutical testing industry or for cellular based therapy. Polyurethanes (PUs) are one group of materials that have shown promise in cell culture. Our recent progress in optimizing a polyurethane coated surface, for long-term culture of human hepatocytes displaying stable phenotype, is presented and discussed.
Biological materials have been widely used in the maintenance and differentiation of pluripotent stem cells 1. While enabling, these biological substrates often contain a myriad of undefined components. Matrigel is a commonly used substrate for stem cell culture and differentiation. Unfortunately, its variable composition influences cell function and phenotype. Although a variety of alternative, more defined biological matrices have been used 2-7, their animal origin or poor scalability makes them unsuitable candidates for industrial manufacture. Therefore the identification of synthetic alternatives, with defined composition and reliable performance, are key goals in stem cell research.
In an attempt to overcome the limitations of undefined cell culture substrates, interdisciplinary collaborations between chemistry and biology have identified synthetic materials with the capacity to support cell phenotype. Synthetic substrates are scalable, cost effective, and can be manufactured into complex 3D structures, mimicking the in vivo environment. Due to these properties synthetic substrates have been widely used to support and drive differentiation of many cell types 8-10.
Advanced and high throughput assays have facilitated the rapid screening of synthetic materials, from large libraries, and delivered novel materials with flexible properties with wide applications in biomedical research and development 11-13. Utilizing high throughput, polymer micro-array screening technology, we rapidly identified a simple polyurethane (PU134), suitable for maintenance of human stem cell derived hepatocytes. This polymer was found to be superior to animal derived substrates with regard to hepatocyte differentiation and function 14-16. We have subsequently optimized the coating conditions, topography and sterilization process to access effects on polymer performance in stabilizing hepatocyte function and lifespan. This has significant implications with regard to understanding fundamentals of hepatocyte biology for cell based modelling and regenerative medicine applications.
The technology here described represents an example of how the surface of a synthetic polymer can be optimized to preserve cell phenotype. We believe that the combination of this technology with an efficient serum free hepatocyte differentiation protocol has the potential to provide a scalable production of hepatocytes for use in in vitro modelling and regenerative medicine.
1. Synthesis of PHNGAD (Poly[1,6-hexanodiol/neopentyl glycol/di(ethylene glycol)-alt-adipic acid]diol)
Scheme 1: Synthesis of PHNAGD. Schematic representation of the synthesis of PHNAGD. PHNAGD was prepared by the reaction of 1,6-Hexanodiol, diethylene glycol, neoppentyl glycol and adipic acid. PHNAGD, Poly[1,6-hexanodiol/neopentyl glycol/di(ethylene glycol)-alt-adipic acid]diol.
2. Synthesis of PU134
Scheme 2: Synthesis of PU134. Schematic representation of the synthesis of polyurethane 134. PU134 was prepared by the reaction of 1.0 equiv of a PHNGAD with 2.0 equiv of a 4,4′-Methylenebis(phenyl isocyanate), followed by the addition of 1.0 equiv of a 1,4-butanediol chain extender.
3. Preparation of PU134 Solutions
4. Coating of Glass Slides with PU134
5. Irradiation of Coverslip
6. Scanning Electron Microscopy
7. Atomic Force Microscopy Observations
8. Cell Culture and Differentiation
9. Cytochrome p450 Functional Assay
10. Immunostaining
Polymer solvent influences the topography of the polymer coated surface
Polyurethane 134 was solubilized in chloroform, either alone or in combination with toluene or tetrahydrofuran or dichloromethane and the glass slides spin-coated with the different formulations. Scanning electron microscopy (SEM) and atomic force microscopy (AFM) were used to characterize the physical properties of the polymer coatings (Figure 1). The coating obtained using toluene or chloroform was not homogeneous, demonstrating an uneven coating with PU134 precipitation (Figure 1A). In contrast, tetrahydrofuran was a suitable solvent allowing the spin coating of a much more uniform surface (Figure 1A). Surface topography was measured by AFM using the root mean square (RMS) and the mean roughness (Ra). PU134 dissolved tetrahydrofuran exhibited a 40% reduction in the roughness in comparison to the other solvents (Figure 1B and 1C). These data demonstrate that the use of tetrahydrofuran as a solvent provides a more uniform coating of PU134 for biological application.
Polymer topography has a significant impact on hepatocyte function
hESC can be efficiently differentiated to hepatic endoderm in vitro, exhibiting many of the functions found in the adult liver 17-20. Hepatic endoderm differentiation was induced and at Day 9 hepatoblast-like cells were apparent, with the majority of cells expressing cytokeratin 19 (99% ± 1.2), α-fetoprotein (99% ± 0.6), and hepatic nuclear factor 4α (97% ± 2.6); and low levels of albumin (20% ± 1.7) (Figure 2). At this point the cells were detached using TrypLE express and replated onto the different polymer coated surfaces. As a measure of metabolic function, cytochrome P450 function was assessed 4 days post-replating. We observed a 2-fold increase in metabolic activity in cells replated on tetrahydrofuran/PU134 coated surfaces (Figure 3). These results demonstrate that hESC derived hepatocyte metabolic activity is improved with a more uniform coating of PU134, this is consistent with previous approaches 21.
Surface sterilization impacts on the bioactive properties of the polymer
The effect of sterilization on PU134 performance was also investigated. Polymer coated glass slides were exposed to UV or gamma irradiation. Phase contrast imaging of PU134 coated glass slides showed no gross differences post UV or gamma irradiation (Figure 4A). These observations were further confirmed by SEM analysis (Figure 4B). The biological performance of PU134 was examined using hESC derived hepatocytes at 10 days post-replating. hESC derived hepatocytes replated on γ-radiated PU134 coated glass slides displayed a 3-fold increase in CYP3A activity over cells replated on UV-radiated PU134 coated glass slides (Figure 4C). These observations demonstrated that gamma-irradiation was the optimal sterilization technique for our purposes.
Figure 1. Optimization of the polyurethane 134 coated surface. (A) Glass slides were coated with a 2% solution of PU134 dissolved in different solvents. Scanning Electron Microscopy (SEM) images of the different coated glass slides show the presence of a homogeneous coated surface and the absence of polymer precipitates when tetrahydrofuran was used compared with toluene, chloroform or mixtures of the solvents (black and white arrows). The images were taken at x1664 magnification and scales bars are shown below the images. (B-C) Atomic Force Microscopy (AFM) was employed to analyze the roughness of the PU134 coated surfaces on selected solvents. Analysis of the roughness parameters RMS (the root mean square) (B) and Ra (the mean roughness) (C) of the different PU134 coated surfaces show that the coating obtained by using tetrahydrofuran as a solvent had the smoothest surface when compared with the rest of the conditions (n=7). Data are expressed as mean ± s.d., p<0.05 is denoted *, p<0.01 is denoted **, and p <0.001 is denoted ***, measured by students t-test in comparison to slides coated with PU134 solubilized in tetrahydrofuran. Error bars represent 1 standard deviation. Please click here to view a larger version of this figure.
Figure 2. Characterisation of the hESC derived hepatoblasts. Immunocytochemistry showing expression of hepatic markers AFP, CK19, HNF4α and Albumin in hESC (H9) derived hepatic endoderm. Negative controls were performed with corresponding immunoglobulin G (IgG) and representative images are shown. The percentage of positive cells and standard deviation were estimated from at least five random fields of view containing at least 300 cells per view. The images were taken at 20X magnification. Data is expressed as mean ± s.d. Error bars represent 1 standard deviation. HNF4α, Hepatocyte nuclear factor 4α; AFP, α-fetoprotein; ALB, Albumin; CK19, Cytokeratin 19, IgG goat, Immunoglobulin G anti-goat, IgG mouse, Immunoglobulin G anti-mouse. Please click here to view a larger version of this figure.
Figure 3. Functional implications of the topography of the PU134 coated surface on the function of hESC derived hepatocytes. Measurement of the Cytochrome P450 3A activity on hESC-derived hepatocytes maintained for 96 hr on glass slides coated with PU134 dissolved in different solvents. An improvement in the in the cytochrome activity on cells maintained on PU134 coated glass slides solubilized with tetrahydrofuran (n=6). Data are expressed as mean ± s.d., p<0.05 is denoted *, p<0.01 is denoted **, and p <0.001 is denoted ***, measured by students t-test in comparison to hESC derived hepatocytes maintained on slides coated with PU134 solubilized on tetrahydrofuran. Error bars represent 1 standard deviation.
Figure 4. Optimizing the sterilization of the coated surfaces. Phase contrast images (A) or SEM images (B) show no gross differences in the PU134 coated surface between γ-radiation or UV radiation (UV) treatments. Phase contrast images were taken at 40X magnification and SEM images at 1,664X magnification. (C) Analysis of the cytochrome P450 3A activity on hESC derived hepatocytes maintained for 10 days on PU134 coated glass slides. An increase in the cytochrome P450 3A activity in cells replated on γ-radiated PU134 coated glass slides when compared with cells replated on UV radiated PU134 coated glass slides. Units of activity are expressed as relative light units (RLU) ml−1 cm−2 of culture surface (n=3). Data are expressed as mean ± s.d., p<0.001 is denoted *** measured by students t-test in comparison to hESC derived hepatocytes maintained on PU134 coated glass coverslips sterilized by γ-radiation. Error bars represent 1 standard deviation. Please click here to view a larger version of this figure.
Primary antibodies | |||
Antigen | Tipo | Company | Dilution |
HNF4α | Rabbit polyclonal | Santa Cruz | 1/100 |
Albumin | Mouse monoclonal | Sigma | 1/500 |
AFP | Mouse monoclonal | Abcam | 1/500 |
Cytokeratin 19 | Mouse monoclonal | Dako | 1/50 |
IgG | Mouse monoclonal | Dako | 1/500 |
Secondary antibodies | |||
Anti-rabbit 568 Alexa Flour | Goat | Invitrogen | 1/400 |
Anti-mouse 488 Alexa Flour | Rabbit | Invitrogen | 1/500 |
Table 1. List of optimized primary and secondary antibodies and concentrations used in this study. HNF4α, Hepatocyte nuclear factor 4α; AFP, α-fetoprotein; IgG, Immunoglobulin G.
Many of the current methods used to generate hepatocytes from stem cells rely on undefined matrices of animal origin. These substrates can be costly and highly variable, affecting cell function and stability, representing a significant barrier to application. Therefore, we performed a screen for synthetic materials which support the culture of stem cell derived hepatocytes. We have identified, a simple polyurethane (PU134), formed by polymerizing PHNGAD, MDI and an extender, that in combination with a robust hepatocyte differentiation approach, stabilizes the hepatocyte phenotype and improves cell function when compared with matrigel 15.
Handling of existing biological matrices, commonly used in culturing and differentiating stem cells such as vitronectin 22, laminin 521 23 or matrigel, is effective for short term maintenance. In contrast, PU134 coated surfaces provide a superior substrate for hepatocyte culture. Moreover, the optimization of surface topography and polymer sterilization have led to further improvements in cell performance, a key factor in delivering human liver models at scale with dependable performance.
The nature of the chain extender and phenyl isocyanate represents one of the critical stages of the process; as elimination or replacement of either component would significantly impair the polymer surface and therefore the cellular attachment and functional activity of stem cell derived hepatocytes. The composition of the polymer affects physical parameters such as elasticity and wettability 24, which has impacts the capacity of the polymer to absorb key extracellular matrix proteins involved in hepatocyte function. In addition, variations in the catalyst, reaction time and temperature affect the molecular weight distribution of the polymer.
The selection of the solvent to solubilize the polymer represents another critical point in the obtaining of an optimized polymer coated surface. We have observed that the nature of the solvent affects the topography of the coated surface, which has direct implications in the function of the cells 25-31. In addition, the spinning time and speed are also crucial in obtaining this uniform and homogeneous coating. Another step to take in consideration is the sterilization procedure applied on the polymer coated surface, as the activity of the cells can be influenced by the sterilization treatment used. This may be due to the presence of sensitive area(s) within the structure of the polymer to different sterilization procedures 32-34.
Current pluripotent stem cell based cell models possess phenotypic and functional limitations. We believe that this optimized polymer coated surface represents an advance in the field, circumventing some of the limitations associated with the use of biological substrates. Furthermore, the possibility of using the polymer within 3D matrices to support the attachment of different cellular types found in the tissue of interest, may further improve cell fidelity.
In conclusion, the use of synthetic materials is becoming increasingly important in the delivery of human soma from pluripotent stem cells. We have developed an optimized surface and coating procedure that is robust and reliably delivers functional human hepatocytes with significant implications for cell based modeling and regenerative medicine.
The authors have nothing to disclose.
D.C.H., M.B. and F.K. were supported by an EPSRC Follow on Fund. B.L-V and D.S. were each supported by MRC PhD studentships. K.C. was supported by funding from the UK Regenerative Medicine Platform.
Synthesis, preparation, coating and characterization of polymer PU134 coated coverslips | |||
Shaker | Edmun Bühler | KS-15 | |
Irradiator | CIS Biointernational | IBL 637 | |
Spin coater | Specialty Coating System | P-6708 | |
Scanning Electron Microscope | Philips | XL30CPSEM | |
Atomic Force Microscope | DimensionV Nanoscope, VEECO | ||
p4-GLO CYP3A4 | Promega | V8902 | |
UV bulb | ESCO | ||
NanoScope analysis software | VEECO | version 1.20 | |
Fluorescence microscope | Olympus | TH45200 | Use Volocity 4 Software |
Tissue culture plates | Corning, UK | 3527 | |
glass slides | Scientific Laboratory Supplies | MIC3308 | |
Diethylene glycol | Sigma–Aldrich | 93171 | |
1,6-hexanediol | Sigma–Aldrich | 240117 | |
Neopentyl glycol | Sigma–Aldrich | 408255 | |
Adipic acid | Sigma–Aldrich | 9582 | |
anhydrous N,N-Dimethylformamide | Sigma–Aldrich | 227056 | |
Diethyl ether | Sigma–Aldrich | 676845 | |
titanium (IV) butoxide | Sigma–Aldrich | 244112 | |
1,4-butanediol | Sigma–Aldrich | 493732 | |
Vacuum oven | Thermoscientific | ||
4,4’-Methylenebis(phenyl isocyanate) | Sigma–Aldrich | 101688 | |
Tetrahydrofurane | Sigma–Aldrich | 401757 | |
Sputter coater | Bal-Tec SCD 050 | ||
Inmunostaining | |||
Phosphate buffer saline (-MgCl2, -CaCl2) | Gibco | 10010031 | Store at room temperature |
PBST, PBS made up with 0.1% TWEEN 20 | Scientific Laboratory Supplies Ltd | EC607 | |
Methanol | Scientific Laboratory Supplies Ltd | CHE5010 | |
Bovine Serum Albumin | Sigma-Aldrich, UK | A7906 | |
MOWIOL 488 DAPI | Calbiochem | 475904 | Made up in Tris HCL and glycerol as per manufacturers instructions |
Cell culture and Functional assay | |||
CYP3A activity pGLO kit | Promega | V8902 | |
Hepatozyme | Gibco | 17705021 | |
TryLE express | Life Technologies | 12604013 |