Abstract

Although surface immobilization of medical devices with bioactive molecules is one of the most widely used strategies to improve biocompatibility, the physicochemical properties of the biomaterials significantly impact the activity of the immobilized molecules. Herein we investigate the combinational effects of cell-selective biomolecules and the hydrophobicity/hydrophilicity of the polymeric substrate on selective adhesion of endothelial cells (ECs), fibroblasts (FBs), and smooth muscle cells (SMCs). To control the polymeric substrate, biomolecules are immobilized on thermoresponsive poly(N-isopropylacrylamide-co-2-carboxyisopropylacrylamide) (poly(NIPAAm-co-CIPAAm))-grafted glass surfaces. By switching the molecular conformation of the biomolecule-immobilized polymers, the cell-selective adhesion performances are evaluated. In case of RGDS (Arg-Gly-Asp-Ser) peptide-immobilized surfaces, all cell types adhere well regardless of the surface hydrophobicity. On the other hand, a tri-Arg-immobilized surface exhibits FB-selectivity when the surface is hydrophilic. Additionally, a tri-Ile-immobilized surface exhibits EC-selective cell adhesion when the surface is hydrophobic. We believe that the proposed concept, which is used to investigate the biomolecule-immobilized surface combination, is important to produce new biomaterials, which are highly demanded for medical implants and tissue engineering.

1. Introduction

For long-term implantation of medical devices, such as vascular grafts, both cellular-compatibility and antithrombogenicity are essential [1, 2]. The realization of functional sustainability has been a challenge for biomaterial chemistry to minimize life-threatening risks.

One major strategy to provide biological functionality (e.g., cell adhesion) for medical applications of polymer materials is immobilization of biomolecules using extracellular matrix (ECM) proteins [36], antibodies [7], peptides [813], and so forth. Cell adhesion is a critical step to regenerate tissues damaged by implantation surgery. For example, endothelialization of vascular grafts can be enhanced by improving adhesion of endothelial cells (ECs) on their surface. Faster endothelialization prevents two risks of restenosis: thrombosis and neointimal hyperplasia [1416]. The monolayer coverage of endothelial cells strongly provides antithrombosis effect. The appropriate endothelial monolayer formation is also the first step of proper cellular organization, which inhibits the uncontrolled growth of smooth muscle cells and fibroblasts that invade from the outer layer of vascular tissue.

Peptides on polymers have shown successful cell adhesive function. RGD (Arg-Gly-Asp), which is the integrin ligand sequence, is one of the most well established biomolecules that provide a cell adhesion function on polymers [17]. Moreover, various peptides from ECMs exhibit a cell adhesion performance. We have reported that short peptides (3 mer to 7 mer) enhance not only cell adhesion [18] but also cell-selective adhesion [19, 20]. An ECM-derived 3 mer peptide (CAG: Cys-Ala-Gly) enhances EC adhesion for endothelialization but inhibits smooth muscle cell (SMC) adhesion inside the electrospun vascular scaffold composed of poly-ε-caprolactone in vivo [21] and inhibits platelet adhesion on a material surface [22].

Through our systematic cell adhesion peptide screening, we have found two classes of adhesion peptides. One exhibits a strict ligand-receptor behavior (RGDS and YIGSR). The other is more closely related to motifs that largely depend on their physiochemical properties and therefore may accept a range of sequence variations. That is, not only the sequence itself [cell-peptide interaction through ligand-receptor (e.g., RGD peptide)] but also the physicochemical property can control cell-selective adhesion [19].

Ile-containing peptides (3 mer to 7 mer) show selective adhesion of ECs, but they show a negative adhesion effect on SMCs and fibroblasts (FBs). Compared to antibodies and ECM-derived large proteins, short peptides can be feasibly synthesized and purified. The assurance of their purity and production costs is advantageous for functionalizing medical materials, but similar to other biological molecules, peptides require skillful immobilization to sustain their original performance. There are several unknown factors that can diminish biomolecule performance, including side effects of immobilization chemistry, structural/directional changes by immobilization, molecular density of immobilization, or combinational effects of biomolecule-polymer compatibility. Understanding the cause of such unexpected effects in biomolecule immobilization is important when designing medical devices.

Additionally, the properties of the polymer itself greatly influence cell adhesion. Wettability [23], elasticity [24], and geometry [25] of the polymer material are critical factors affecting biocompatibility. Previously, we reported that the level of hydrophobicity of polyNIPAAm can change the cell adhesion performance of the same immobilized-RGDS (Arg-Gly-Asp-Ser) peptide [2628].

Based on these observations, we hypothesize that there should be a combinational effect of biomolecules and the immobilized polymer status that may inhibit/enhance the total functionality. To investigate such a biomolecule-polymer combinational effect, we designed a cell assay platform that can compare the total performance of the target biomolecules combined with different polymer properties by applying thermoswitchable polyNIPAAm technology (Figure 1). Altering the status of the biomolecule-immobilized polyNIPAAm by temperature allows the performance of the same immobilized biomolecule to be assayed as a function of the polymer properties.

In this work, we apply the cell assay platform of poly(NIPAAm-co-CIPAAm) [2629] to compare cell adhesion performances. Specifically, the changes in the cell adhesion performance and the preference among three different cell types (ECs, FBs, and SMCs), which we refer to as “cell-selective adhesion” (Figure 1), are evaluated. The results indicate that immobilized biomolecule performances depend on the combination of the polymer status and appropriately selecting the immobilization polymer may sustain or even enhance the cell-selective adhesion performance of biomolecules.

2. Materials and Methods

2.1. Preparation of the Poly(NIPAAm-co-CIPAAm) Cell Assay Platform

The poly(NIPAAm-co-CIPAAm) cell assay platform was prepared using a surface-initiated atom transfer radical polymerization (ATRP) technique [29] (Figure 2). Water-repellent printed slide glasses and regular slide glasses (10 mm × 25 mm) (Matsunami Glass Industry, Tokyo, Japan) were exposed to UV ozone for 10 min for cleaning. Then the clean glass platform was placed in a glass container with (chloromethyl)phenylethyl-trimethoxysilane (Gelest, Inc., Morrisville, PA, USA) for the silanization reaction for 3 h at 90°C and subsequently baked for 1 h at 110°C. NIPAAm (Kohjin, Tokyo, Japan) was purified by recrystallization from n-hexane (Wako Pure Chemical Industries, Osaka, Japan).

2-(Benzyloxycarbonyl)isopropylacrylamide (CIPAAmBz) was synthesized and purified according to the previously reported protocol [30]. On the surface of the silanized glass platform, a poly(NIPAAm-co-CIPAAmBz) layer was grafted in 2-propanol (Kanto Chemical, Tokyo, Japan) with a molar ratio of 100 : 1 (NIPAAm : CIPAAmBz) with a free ATPR initiator at room temperature for 17 h. In a typical procedure, 17.924 g (2 mol/L) of NIPAAm, 401 mg (20 mmol/L) of CIPAAmBz, 72 mg (8.99 mmol/L) of Cu(I)Cl (Kanto Chemical), and 10 mg (1.00 mmol/L) of Cu(II)Cl2 (Wako Pure Chemical Industries) were dissolved in 80 mL of the degassed solvent in a glove box under a nitrogen atmosphere. The silanized glasses, 200 mg (10.8 mmol/L) of Me6TREN (Mitsubishi Chemical Holdings, Tokyo, Japan) and 133 mg (10.7 mol/L) of 4-ethylbenzyl chloride (Tokyo Chemical Industry, Tokyo, Japan), were added to the above solution. The reaction was terminated by exposing the solution to air. The polymer layered platform was rinsed with 2-propanol and methanol (Kishida Chemical, Osaka, Japan) and dried under a vacuum. Deprotection of CIPAAmBz in the polymer layer was carried out by acidic hydrolysis with methanesulfonic acid (Wako Pure Chemical Industries). In a typical procedure, 37.5 mL (15 vol%) of methanesulfonic acid was dissolved in 212.5 mL of dichloromethane (Kanto Chemical). The polymer-grafted cell assay platform was deprotected by acidic hydrolysis with 15 vol% methanesulfonic acid in dichloromethane at room temperature for 17 h. The activated platform surface was then rinsed with dichloromethane and methanol for the biomolecule immobilization step.

To check the quality of the synthesized polymer, the molecular weight of the free polymer was determined by a gel permeation chromatography (GPC) system (TOSOH TSK-GEL α-2500, Tosoh, Tokyo, Japan) equipped with a refractive index detector (RI-2031) at 40°C. The polymer solution was first dialyzed with pure water and then applied to GPC. The GPC measurement confirmed that the molecular weight () was 6.95 × 103 g/mol (Table 1).

2.2. Biomolecule Immobilization on Poly(NIPAAm-co-CIPAAm) Cell Assay Platform

Biomolecules (di- or tetrapeptides) were immobilized onto CIPAAm via the carboxyl groups with an equal molar amount of 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide hydrochloride (EDC) (Dojindo Laboratories, Kumamoto, Japan) in pure water under a humid atmosphere at room temperature for 17 h. Then the platform was rinsed with pure water and dried under a vacuum until cell assay usage. Gly-Arg (mono-Arg), Gly-Ile (mono-Ile), Gly-Arg-Arg-Arg (tri-Arg), and Gly-Ile-Ile-Ile (tri-Ile) (>90% purity) synthesized by Biomatik (Cambridge, ON, Canada) and RGDS (>98% purity) purchased from Peptide Institute (Osaka, Japan) were used as biomolecules for immobilization.

2.3. Characterization of the Biomolecule-Immobilized Poly(NIPAAm-co-CIPAAm) Cell Assay Platform

To characterize the cell assay platform, X-ray reflectivity (XRR) was performed with a Rigaku ATX-G (Rigaku, Tokyo, Japan) operating with Cu Kα radiation (0.154 nm). The grafted polymer density, (chains/nm2), of the fabricated polymer layer was calculated using the equation , where is the polymer layer thickness (nm), is the polymer layer density (g/cm3), is Avogadro constant, and is the number-average molecular weight of the free polymer chains [29].

The contact angle (CA) of the cell assay platform was measured in water to mimic an actual in vitro situation. On the cell assay platform facing downward in a transparent vessel filled with phosphate buffered saline (PBS) (Wako Pure Chemical Industries), the CA of the captured air bubble was measured by FACE CA-XP (Kyowa Interface Science, Saitama, Japan) according to the previously reported protocol [31]. Then the measured CA of the air bubble was subtracted from 180° to describe the CA in this work. The PBS temperature was regulated with a temperature-controlled circulator (RE104, Lauda, Kanagawa, Japan). The result of CA was expressed as the mean of three measurements with the standard deviation (SD). The significance of CAs between 37°C and 20°C was tested by Student’s t-test. The significance of the measured CA between samples was evaluated by the one-way analysis of variance (ANOVA).

2.4. Cells and Cell Cultures

Normal human umbilical vein ECs (Kurabo, Osaka, Japan) were maintained in HuMedia-EG2 (Kurabo). Human aorta SMCs (Kurabo) were maintained in a Complete Medium Kit with Serum with CultureBoost (Cell Systems, Kirkland, WA, USA). Normal human adult dermal FBs (Kurabo) were maintained in Dulbecco’s modified Eagle’s medium (DMEM) (Wako Pure Chemical Industries) with 10% fetal bovine serum (Nichirei Biosciences, Tokyo, Japan) and 1% penicillin streptomycin (Wako Pure Chemical Industries). Cells were maintained at 37°C and 5% CO2 and were used within five passages.

2.5. Cell Adhesion Assay

The cell adhesion assay was carried out with the previously described protocol with some modifications [29]. Viable cells stained with Calcein-AM (Dojindo Laboratories) for 1.5 h were seeded on the cell assay platform with droplets (1.56 × 104 cells/cm2). To switch the hydrophobic/hydrophilic property of poly(NIPAAm-co-CIPAAm), the seeded platform was first cultured at 37°C. After cell adhesion for 1 h, cellular images were obtained on the platform by fluorescence microscopy (X71, Olympus Corporation, Tokyo, Japan) using MetaMorph (Molecular Devices, LLC, Sunnyvale, CA, USA) controlled by an electric stage. Fluorescent cellular images () were processed using MetaMorph to count the cellular numbers. Subsequently, the platform was transferred to a 20°C atmosphere for property switching from the hydrophobic status to the hydrophilic status. Upon changing the polymer status, the cells were cultured for 1 h for cell adhesion. Then their cellular images were obtained in the same manner. The results of cell adhesion were expressed as the mean of six cellular images with the standard deviation (SD). The significance of the data between two conditions was tested by Student’s t-test, and the significance of the data among other conditions was tested by one-way ANOVA.

3. Results

3.1. Characterization of the Poly(NIPAAm-co-CIPAAm) Platform for Cell Assays

To investigate the combinational effect of a biomolecule and its immobilized polymer property, we constructed a poly(NIPAAm-co-CIPAAm)-grafted assay platform. By using thermoresponsive poly(NIPAAm-co-CIPAAm), the platform can change the status of the polymer with the same immobilized biomolecules.

By measuring XRR on the assay platform, the thickness and density of the grafted layer are estimated as  nm and  g/cm3, respectively (Table 1). The fabricated polymer graft has a graft density of 0.30 chains/nm2, which reproduces the previous data [29, 32]. The measurement of the temperature-dependent transmittance change also confirms that lower critical solution temperature (LCST) is between 20°C and 37°C (Supporting Information Figure S in Supplementary Material available online at http://dx.doi.org/10.1155/2016/2090985). This result indicates that the grafted polymer can switch its hydrophilic/hydrophobic property by thermal stimulation (20°C or 37°C).

As a property descriptor, the CA was measured to describe the wettability of this platform; it measures 40.0° (SD = 0.8°) at 20°C and 44.6° (SD = 1.7°) at 37°C (Figure 3). Although the difference in CAs between these two temperatures is significant for all samples [20°C versus 37°C at blank (without biomolecules) (), mono-Arg (), mono-Ile (), tri-Arg (), and tri-Ile ()] by the t-test, the difference between immobilized biomolecules in the same temperature is insignificant ( at 37°C and at 20°C) by one-way ANOVA. Therefore, our poly(NIPAAm-co-CIPAAm) surface provides a greater property effect by thermal stimulation independent of biomolecules immobilization.

3.2. Cell Adhesion on the Biomolecule-Immobilized Poly(NIPAAm-co-CIPAAm) Platform

On the established cell assay platform, cell adhesion was assayed at either 37°C or 20°C. Since the biomolecular composition and biomolecule-polymer immobilization are the same in both conditions, the impact of the different biomolecule functions on the combinational effect of the polymer property can be compared. Figure 4(a) shows the visualized cell adhesion results for the three cell types. The images () are quantified by image analysis (Figure 4(b)).

First, the blank (without biomolecule) surface at 37°C and 20°C indicates that the hydrophobic property of poly(NIPAAm-co-CIPAAm) enhances cell adhesion of ECs () and SMCs (). FBs are more insensitive to such hydrophilic/hydrophobic property changes, showing strong adhesion in both conditions. Second, the RGDS-immobilized surfaces at both 37°C and 20°C indicate that all types of cells are capable of high cell adhesion performance despite the polymer property change.

Third, mono-Arg- and tri-Arg-immobilized surfaces show similar patterns of cell adhesion for the three types of cells in both temperature conditions. Although SMCs show universally weak adhesion in all conditions, FBs show some adhesion to both mono-Arg and tri-Arg (much weaker than the RGDS peptide effect) (37°C versus 20°C: ). ECs show weak adhesion to both mono-Arg and tri-Arg for hydrophilic conditions at 20°C, but its adhesion is recovered when the polymer is more hydrophobic (at 37°C) (37°C  versus 20°C: ). A similar adhesion pattern is observed on the mono-Ile-immobilized surface with FBs. However, the adhesion performance greatly changes with ECs on the tri-Ile-immobilized surface (37°C versus 20°C: ). When the polymer property is hydrophobic, the cell adhesion performance increases more than 2.5-fold (the ratio of EC adhesion on tri-Ile-immobilized surface at 37°C to 20°C). Although the overall cell adhesion performance of tri-Arg and tri-Ile is much weaker than RGDS, the EC adhesion performance of tri-Ile due to the change in the polymer property is superior to RGDS.

3.3. Cell-Selective Adhesion Performance and Biomolecule-Polymer Combination Effect

Compared to the universal strong cell adhesion performance of RGDS peptides, cell-selective adhesion preferences between ECs, SMCs, and FBs were examined in other conditions (Figure 4(b)). The native poly(NIPAAm-co-CIPAAm) platform surface (blank) shows FB-selective adhesion at 20°C, but the material surface negatively affects EC and SMC adhesion (FB versus others: ). Although the FB-selectivity is slightly weakened by mono-Arg immobilization at 20°C (), the significantly enhanced FB-selectivity at 37°C () may be due to the combinational effect of the polymer hydrophobicity at 37°C (Figure 4(b)). In contrast, the tri-Arg-immobilized surface also exhibits a slight FB-selectivity when the surface is hydrophilic at 20°C (), which significantly weakens FB-selectivity at 37°C (cell adhesion number of FBs were similar to ECs). Another enhancement of the cell-selective adhesion performance occurs with ECs on a tri-Ile-immobilized surface. The hydrophilic polymer effect enables a rather weak adhesion performance of tri-Ile on ECs and FBs. However, when the hydrophobicity of the polymer increases, the adhesion performance to ECs is enhanced greatly, resulting in a 14.6-fold increase in the selective performance () to discriminate between ECs and SMCs (the ratio of EC adhesion to SMC adhesion on tri-Ile-immobilized surface at 37°C). These results indicate that there are effective combinational effects between an immobilized biomolecule and its immobilized polymer.

4. Discussion

To provide an effective biological function on medically used polymer, biomolecular immobilization is an effective strategy. Because both the immobilized biomolecule and its immobilization polymer strongly affect cell adhesion, this study investigates whether there are combinational effects, especially on cell-selective adhesion. To compare the total cell adhesion performance of a biomolecule-immobilized polymer by switching the property of polymer, we designed a cell assay platform using a thermoresponsive polymer.

CA, which is an indicator of the wettability of a biomaterial, has been studied; there are some wettability areas that are preferred for cell adhesion [23]. Additionally, for the plastic culture plates on the market, their surface wettability is controlled to achieve certain condition. For example, when we examined several commercially available tissue culture-treated multiwell plates (6-well plates) as basic data, CA in the air state ranges from 49.3° to 93.8° (plate 1: Greiner bio-one, Cellcoat Collagen Type I, cat. 657950, lot 13-29-02-89) 47.0° (SD = 1.0°), (plate 2: BD Biosciences, BD PureCoat Amine 6-well plate, cat. 4721, lot 3053352) 49.3° (SD = 2.4°), (plate 3: Corning, Corning CellBIND Surface Polystyrene Sterile, cat. 3335, lot 22814004) 53° (SD = 2.5°), (plate 4: Greiner bio-one, 6 Well Advanced TC Plate, cat. 657960, lot E14113SB) 70.5° (SD = 2.6°), (plate 5: Falcon, Multiwell PRIMARIA 6-well, cat. 353846, lot 3269538) 83.9° (SD = 1.7°), (plate 6: Falcon, Multiwell 6-well, cat. 353046, lot 1272703) 85.9° (SD = 5.6°), (plate 7: Greiner bio-one, 6 Well Cell Culture Plate sterile with lid, cat. 657160, lot E9070HI) 88.8° (SD = 2.2°), and (plate 8: Thermo Fisher Scientific, Nunclon Delta Surface, cat. 140675, lot 7117287) 93.8° (SD = 0.9°). Because all of the products show a good cell culture performance, we could not find a simple correlation between CA and cell adhesion performance. The reality is that the data to explain such rules between cell adhesion performance and the polymer surface property is limited. In other words, since there are several varieties of commercially available polymers that can culture cells with different CAs, it is extremely difficult to select the appropriate culture plate to evaluate the expected performance of immobilized biomolecules on its surface. Vast combinations of plates and immobilization conditions had to be assessed to evaluate the function of immobilized screened biomolecules.

In this work, our data provides the possibility that an immobilized biomolecule, such as an amino acid or peptide, is greatly affected by the combinational effect of the immobilized polymer property. Although our platform shows small CA differences between its hydrophilic/hydrophobic statuses, such a combinational effect is large, especially in enhancing cell-selective adhesion.

Proteins included in the serum that adsorb on the polymer surface are always an influential factor in cell adhesion. We evaluated the adsorption rates of two types of ECM-derived proteins, fibronectin and collagen type IV, on our cell assay platform (Supporting Information Table S1). Our data indicates that the amount of protein adsorption is insignificant on our platform. Additionally, our previous research indicated that cell-selective adhesion peptides maintain their effects in a cell adhesion test with a serum containing medium [19]. Therefore, we consider that our cell adhesion assay data predominantly reflects the biomolecule-polymer combination effect.

Through this study, we show that the cell adhesion function of biomolecules can be greatly influenced by the combination of the biomolecule-immobilized polymer property. Interestingly, the cell-selective adhesion performance is more strongly influenced by the immobilized polymer effect. We have shown that such cell-selective adhesion can be provided not only by the peptide sequence, but also by the physicochemical property of the peptides [19]. In particular, our data shows that Ile-containing peptides can exhibit EC-selective adhesion and inhibit adhesion of SMCs and FBs [19]. Accordingly, this study employs physicochemical characteristic molecules, such as Arg-containing molecule (positively charged) and Ile-containing molecule (hydrophobic). The positive charge provided by Arg is preferred by FBs; however, the effect of tri-Arg is smaller than mono-Arg at both polymer conditions (37°C and 20°C). The hydrophobicity provided by Ile is preferred by both ECs and FBs, but the selectivity is greatly enhanced by the combinational effect with the polymer hydrophobicity. It is noteworthy that the EC-selectivity of tri-Ile reproduces our past results [19]. Although the difference between mono-Ile and tri-Ile at the same temperature is insignificant in the macroscopic characterization (e.g., CA), ECs can recognize the difference in the number of Ile residues and preferably adhere to tri-Ile rather than mono-Ile ( at both temperatures).

Since we have been screening cell-selective adhesion peptides with peptide microarrays [1821], our next challenge is to select a better polymer to maximize each peptide function for medical usages. We also plan to apply our tri-Ile-immobilized surface to label-free cell purification. By using the EC-selective capture performance at 37°C with its EC release performance at 20°C in only 2 h, it can serve as a feasible EC condensation protocol in primary cultures.

In this work, we focus on the surface wettability to characterize our platform surface because a hydrophobicity/hydrophilicity switch is the most dominant change in poly(NIPAAm-co-CIPAAm). However, other descriptors can describe the biomolecule-polymer combinational effect, such as the surface charge, rigidity, or roughness. We actually measured the zeta potentials of biomolecule-immobilized surfaces by DelsaNano HC Particle Analyzer (Beckman Coulter Inc., Brea, CA, USA). However, we did not find a clear correlation with its charged rates compared to our present CA data (Supporting Information Figure S2). Since our data suggests that the design of biomolecule-immobilized polymer materials can be more integrated via a detailed examination of combinational effects, our next objective is to extend this combinational effect investigation by evaluating the influence of other polymer properties characteristics.

5. Conclusion

To design an improved cell-selective adhesion function on medically used biomaterials, the combinational effect of surface-immobilized small biomolecules and the immobilization polymer property were studied. By establishing the poly(NIPAAm-co-CIPAAm) platform that changes the polymer property with the same biomolecule-polymer composition for cell adhesion assay, we found that the cell-selective adhesion performance is greatly affected by the hydrophobicity of the polymer. These results suggest that appropriately selecting the polymer is extremely important to functionalize immobilized biomolecules. Hence, this work should be important for designing functionalized biomaterials for advanced regenerative therapies.

Competing Interests

The authors declare that they have no competing interests.

Acknowledgments

Part of this work was supported by Nanotechnology Platform Program (Molecule and Material Synthesis) of the Ministry of Education, Culture, Sports, Science and Technology (MEXT), Japan. Rio Kurimoto acknowledges technical support of T. Takeshima and R. Oguri (Nagoya University).

Supplementary Materials

Temperature-dependent transmittance changes for free poly(NIPAAm-co-CIPAAm) (Figure S1), Zeta potential analysis of the fabricated substrate surfaces (Figure S2) and Adsorption of fibronectin and collagen type IV on fabricated substrates (Table S1).

  1. Supplementary Material