Protein Pattern Assembly by Active Control of a Triblock Copolymer

Manipulating location, polarity, and outgrowth length of neuron-like pheochromocytoma (PC-12) cells on patterned organic electrode arrays. Yu-Sheng Hs...
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Protein Pattern Assembly by Active Control of a Triblock Copolymer Monolayer

2006 Vol. 6, No. 12 2763-2767

Chao Yung Fan,† Katsuo Kurabayashi,*,†,‡ and Edgar Meyho2 fer*,‡,§ Department of Electrical Engineering and Computer Science, Department of Mechanical Engineering, and Department of Biomedical Engineering, UniVersity of Michigan, Ann Arbor, Michigan 48109 Received July 30, 2006; Revised Manuscript Received October 11, 2006

ABSTRACT We present an electrically programmable technique that can rapidly assemble proteins into high-resolution, arbitrarily shaped patterns. Controlled protein adsorption is achieved by switching the nanoscale surface arrangement of a triblock copolymer monolayer on microelectrodes in an engineered microfluidic device via an electric potential. Our technique is the first capable of configuring differential protein densities into patterns by varying the applied control voltage, providing the possibility to tune signals for complex analytes, test conditions, or quantification.

The ability to precisely immobilize proteins on surfaces in well-defined patterns plays a critical role in the advancement of bioelectronics, proteomic research,1,2 tissue engineering,3 and clinical diagnostics.4,5 Previous research has made significant efforts to develop a wide variety of protein patterning methods, such as nanoimprint lithography,6 e-beam lithography,7 microstamping,8 ink-jet printing,9 dip-pen lithography,10 and protein laser printing.11 However, several drawbacks, including time-consuming fabrication or surface treatments, tedious serial patterning, and the need for complex, expensive instrumentation during the patterning process, limit the use of these techniques for various future applications we envision for these techniques. In addition, it is frequently not possible to rapidly change protein patterns or configure devices during testing. Initial work on thermally activated polymer films12,13 demonstrated the feasibility of programmable protein patterning, but the resulting protein patterns were nonuniform and of limited resolution (∼200 µm). Consequently, it is desirable to develop new protein patterning techniques capable of varying the surface density of immobilized protein in a spatially programmable manner. We believe that such advances will make it possible to precisely isolate, detect, quantify, or manipulate biomolecules. To address the above challenges, we developed a microfluidic system that incorporates a programmable patterning technique. Our technique generates high-resolution protein patterns in minutes and has the ability to modulate the density * Corresponding authors. E-mail: [email protected], meyhofer@ umich.edu. † Department of Electrical Engineering and Computer Science. ‡ Department of Mechanical Engineering. § Department of Biomedical Engineering. 10.1021/nl061780y CCC: $33.50 Published on Web 11/11/2006

© 2006 American Chemical Society

of immobilized protein molecules. The technique combines the electrowetting-on-dielectric (EWOD) phenomenon14 and steric repulsion of proteins by a monolayer of Pluronic F108 (BASF) triblock copolymers. The proposed voltage-controlled patterning employing EWOD does not subject protein molecules to direct current or electrolysis and avoids exposure of proteins to heat, radiation, physical stresses, solvents, or dehydration as do some of the previous methods.8-13,15 EWOD, which has been used for microscale manipulations of liquids16,17 can locally control, via a voltage bias across the dielectric layer, the wettability or hydrophobicity of the dielectric surface. On the other hand, Pluronic copolymers have been widely studied owing to their biocompatibility and antifouling properties.18-21 Pluronic copolymers are triblock copolymers composed of a center hydrophobic poly(propylene oxide) (PPO) domain and two flexible hydrophilic poly(ethylene oxide) (PEO) chains, which are attached at each end of the center PPO domain (Figure 1c).20 Different PPO and PEO chain lengths of copolymers in the Pluronic copolymer family give some variations in Pluronic’s antifouling properties.20,21 Antifouling properties of Pluronic copolymers come from the fact that the Pluronic copolymer’s hydrophobic PPO domain binds strongly to hydrophobic surfaces via hydrophobic-hydrophobic interactions, leaving the flexible hydrophilic PEO chains free in solution to repel proteins and other adsorbents from the surface by steric repulsion.19 Therefore, we hypothesize that by switching a hydrophobic surface, which has been coated with a monolayer of Pluronic copolymers, to a hydrophilic state via EWOD (1) some Pluronic copolymers would detach from the surface due to

Figure 1. Conceptual drawings showing the patterning device design and its operating principle. (a) A three-dimensional view of the microfluidic patterning device. The actual device has approximate chamber size of 2 cm × 2 cm × 200 µm and is assembled by attaching a substrate containing the patterning structures to a microscope slide using ∼200 µm thick double-sided mounting tape. (b) Top view showing key electrode arrangements used for protein patterning. The addition of a “grounding electrode” around the patterning electrodes increases the protein pattern resolution by eliminating floating voltages. For visual clarity, the “grounding electrode” is omitted from other figures. (c) Principal device operation in a cross-sectional view. STEP 1: Pluronic copolymers form a monolayer on the device surface. STEP 2: Activation of selected patterning electrodes suppresses the Pluronic’s steric repulsion and allows proteins to be adsorbed. STEP 3: Unbound proteins are removed from the microfluidic chamber, leaving the desired protein patterns. STEP 4: Additional protein patterns may be created on the device structure by repeating STEPS 2 and 3.

reduced hydrophobic-hydrophobic interactions and (2) hydrophilic PEO chains could collapse onto the surface by comparatively weaker hydrophilic-hydrophilic binding.22 Both conditions suppress Pluronic’s steric repulsion, thus allowing proteins to be adsorbed to the surface. On the basis of these properties, we expect that a hydrophobic surface with a monolayer of Pluronic copolymers can be readily switched from a protein-repelling to a protein-adsorbing state by controlling the wettability of these surfaces. To verify our hypothesis, we designed and fabricated a simple microfluidic system that incorporates the required patterning structures (Figure 1). All electrodes consist of 200 nm thick indium-tin oxide (ITO) and down to 3 µm in width. An approximately 800 nm dielectric film of Parylene C is deposited over the device surface, which contains the patterning structures. This film is hydrophobic as indicated by the contact angle of about 90° and has been tested to be electrically stable up to the breakdown voltage in excess of 100 V, which is beyond the 60 V maximum operating voltage used here. The Pluronic copolymer used for forming the 2764

monolayer on top of the hydrophobic Parylene C layer is Pluronic F108, which has a PEO chain length of 128 monomer units and PPO chain length of 54 monomer units.21 Since each monomer length is ∼0.35 nm,23 a fully extended hydrophilic PEO chain length in solution would be ∼45 nm. The solution in the microfluidic device is referenced with a “solution biasing electrode” (Figure 1), and regions not to be patterned are inactivated by grounding them to the “solution biasing electrode”. As outlined above, we expect that the localized voltage drop associated with an activated electrode leads to a hydrophobic-to-hydrophilic transition of the Parylene C dielectric layer on top of the electrode, causing the Pluronic copolymer monolayer in this region to collapse or be repelled from the surface, which leads to protein binding in this region. The protein patterning is carried out as follows: Initially (step 1, Figure 1c), a monolayer of Pluronic copolymers is formed on the device surface by immersing the surface into a 2.5 mg/mL Pluronic F108 solution for 10 min. To pattern proteins, a bias voltage is applied to the selected patterning Nano Lett., Vol. 6, No. 12, 2006

Figure 2. Experimental verification of the programmable protein patterning. The distribution of fluorescently labeled BSA has been quantitatively characterized with high-resolution light microscopy. (a) Fluorescence micrograph and intensity of two adjacent patterning electrodes. The pattern on the right was activated by applying a 60 V bias, while the left pattern was inactivated with a 0 V bias. The inactivated electrode (left) is outlined by a narrow gap in the ITO. (b) Fluorescence micrograph of a 3 µm wide swirl protein pattern and its intensity profile with estimated protein density. (c) Arbitrarily shaped protein patterns like the letters “UM” and a finger pattern. The transmission differences between ITO-coated and non-ITO-coated regions were corrected in the intensity profiles (see the Supporting Information, Method).

electrodes, and then 300 µL of ∼0.4 mg/mL fluorescently labeled protein in 1 mM K-PIPES buffer (pH 6.8) is introduced into the chamber (step 2, Figure 1c). For initial device characterizations we used rhodamine-labeled bovine serum albumen (TMR-BSA). Protein molecules are allowed to bind to the surface for 3 min before unbound protein molecules are washed away (step 3, Figure 1c). Protein patterns established in this manner were quantitatively characterized by fluorescence microscopy and digital CCD video microscopy. In subsequent steps (step 4, Figure 1c), other electrodes can be activated and exposed to different proteins to establish complex patterns by repeating steps 2 and 3. The programmability and resolution of the proposed patterning method were demonstrated by selectively activating electrodes (60 V bias voltage) of various shapes and patterning fluorescently labeled BSA as outlined above (Figure 2). Fluorescence microscopy showed that proteins were consistently confined with high resolution (better than 3 µm) on the activated electrodes, while inactivated electrodes (0 V, Figure 2a) did not attract proteins above the background level. Intensity profiles (graphs in Figure 2, which correspond to yellow dashed lines in the images) quantitatively confirmed the selectivity and uniformity of our protein patterning technique. The absolute density of immobilized molecules in patterned regions was determined by calibrating the fluorescence intensity from the quantized bleaching behavior of fluorophores and the known labeling stoichiometry of our BSA preparations (see the Supporting Information, Method). We observed that under our experimental conditions a 3 min patterning interval is sufficient to bind ∼500 BSA molecules/µm2 (∼160 arbitrary intensity units (AU) of our 12 bit digital CCD camera) to an activated region. These adsorbed protein densities are consistent with our working hypothesis and experimentally observed monolayer densities of BSA on Parylene C of about 11 000 Nano Lett., Vol. 6, No. 12, 2006

molecules/µm2. Also, the intensity profiles clearly show that the binding of protein to inactivated electrodes is low and indistinguishable from unpatterned areas. To demonstrate that the described patterning method is not limited to BSA, but represents a technique that is generally applicable to different protein molecules, we repeated our patterning experiments with casein. The data in Figure S3 (Supporting Information) show that casein behaves similar to BSA: casein’s adsorption to the substrate surface was confined with high contrast to electrodes activated by bias voltages of 60 V while the background adsorption remained low. These data suggest that our method holds significant potential for programmable patterning a large variety of protein molecules other than those examined here. Furthermore, we characterized how protein patterns can be sequentially configured with our technique (Figure 3). When three patterning electrodes were consecutively activated with a 60 V bias voltage and exposed to protein probes, they were indeed successively patterned. A fourth inactivated electrode served as a reference and remained unpatterned during the entire procedure. The images in Figure 3 reveal a progressive increase in the fluorescence intensity of patterned areas (by ∼19.4 ( 4.5%) following each protein patterning. This progressive increase in pattern intensities was expected as the voltage bias remained on the previously activated electrodes throughout the sequential patterning; however, this behavior is prevented by switching off the bias voltage to previously activated electrodes when a new set of electrodes are being patterned (see the Supporting Information, Figure S1). In addition, the experiments reported in Figure 3 show that, even 1 h after the removal of the electrode bias, protein patterns remain intact with ∼78.0% ( 11.7% of the original signal retained (see the Supporting Information, Figure S2), which suggests that the majority of protein molecules are bound irreversibly on 2765

Figure 3. Sequential protein patterning. We initially activated pattern “1” with a 60 V bias (while others are inactivated with a 0 V bias) and introduced a BSA solution into the chamber. After a 3 min wait, unbound BSA proteins were washed out with a protein-free buffer solution, leaving behind adsorbed proteins on pattern “1”. Subsequently, the same procedure was repeated for pattern “2” and then for “3”. During these sequential patterning steps, the bias on previously activated electrodes was maintained. Pattern “4” remained inactivated to serve as a reference. One hour after the bias to the electrodes had been removed, the protein patterns were still intact, retaining 78.0% ( 11.7% of the original protein density (compare to the Supporting Information, Figure S2). Electrode patterns that have not been activated are outlined by the gap in ITO.

Figure 4. Protein surface density (a) and hydrophobicity (b) as a function of applied voltage bias. The insert in (a) shows a representative fluorescence microscopy image of four patterns to which differential bias voltages were applied. Quantitative measurements reveal a nonlinear rise in the protein surface density with increasing voltage bias. The data points (mean ( standard deviation, N ) 18) were averaged from three independent experiments and a cubic polynomial was fitted to the data. (b) To relate this nonlinear response to the hydrophobicity of the surface, we characterized the contact angle variation from an electrowetting experiment using a sessile drop setup (as shown in the insert). Data from four different experimental devices were averaged, and the mean and standard deviation were plotted. The surface hydrophobicity declines nonlinearly up to a bias voltage of 60 V; the dashed line represents a least-squares fit of eq 1 to the data. A regression analysis of the dependence of the protein surface density on the contact angle suggests that these two parameters are linearly related (P < 0.001). Since the contact angle saturates around 60 V, this value presents the practical operating limit for the device.

the hydrophobic surface24 and that protein patterns could possibly be used even after the electrical connections are removed. Finally, we present evidence that our technique allows us to quantitatively control protein surface densities. When we applied different bias voltages to individual patterning electrodes, the observed protein surface densities varied accordingly (Figure 4a): surfaces that were activated with lower bias voltages adsorbed fewer proteins than those activated by higher voltages, resulting in a nonlinear dependency. To examine the mechanistic basis of this behavior, we characterized the hydrophobicity of the Parylene C film via contact angle measurements using a sessile drop method as shown in Figure 4b (see Supporting Information, Method). The contact angle declined nonlinearly from approximately 90° to 55° for voltages in the range from 0 to 60 V as predicted by cos θ ) cos θ0 + 2766

0d 2 V 2dσlv

(1)

where θ is the contact angle at a given bias voltage V, θ0 is the initial contact angle, d and d are the thickness and dielectric constant of the dielectric layer, respectively, and σlv is the surface tension between the liquid droplet and the ambient gas.14 We selected a maximum operating voltage for the device of 60 V since bias voltages higher than that did not further decrease the contact angle. Possible mechanisms for this contact angle saturation have been described previously (e.g., charge trapping in the dielectric), but the exact nature of this behavior remains unresolved.14,25 A regression analysis showed that the change in hydrophobicity, as characterized by the contact angle measurements (before reaching saturation), is directly inversely proportional (R2 > 0.99) to the patterned protein densities (P < 0.001). The nonlinear voltage dependence of the protein surface density is therefore a consequence of the nonlinear voltage dependence of the contact angle. This supports the overall hypothesis that our voltagecontrolled protein patterning technique is driven by changes Nano Lett., Vol. 6, No. 12, 2006

in the hydrophobicity of the Pluronic copolymer-coated surfaces. In conclusion, we successfully implemented a new, voltage-controlled protein patterning technique that makes it possible to control protein binding to the surface of microfluidic chambers in the presence of monolayers of Pluronic triblock copolymer by modulating the surface wettability. We demonstrated the feasibility of our technique by using fluorescently labeled BSA and casein molecules as model systems and generated complex protein shapes with about 1 µm resolution on lithographically patterned electrodes. The technique is fast, portable, and programmable. We demonstrated that the approach is well suited to create arbitrarily shaped patterns of these proteins with configurable surface densities by using lithographically defined electrodes. We also showed that proteins can be patterned in sequence, but more detailed, quantitative work is necessary to determine possible cross contaminations that result from patterning different protein species in sequence. A number of challenges remain to demonstrate the full potential of this protein patterning method. Research is now under way to further investigate the versatility and adaptability of EWOD-based protein patterning by investigating a variety of different proteins, their activity, and possible applications. We believe that our protein patterning process can support submicrometer resolution. If true, this will allow us to develop high-resolution, multiplexed protein patterning on multipixel electrode arrays. Moreover, the technique’s programmability and flexibility in the shape of the protein patterns could play an important role in tissue engineering, cell studies, nanomolecular systems, and bioelectronics. We note that the presented technique holds significant potential for future developments of configurable devices, especially on-site applications that can afford little patterning equipment but require rapidly arranging biomolecules into complex, highdefinition patterns. Acknowledgment. We thank Y.-W. Lin for assistance in electrode lithography, M.-T. Kao for advices on protein labeling, and C.-T. Lin for advices on device fabrication. This work was supported by NSF, Yamatake Co., Japan, and REA Fellowship from the University of Michigan to C.Y.F. Supporting Information Available: Experimental methods and figures showing an alternative way to sequentially

Nano Lett., Vol. 6, No. 12, 2006

pattern proteins, relative fluorescence signal vs time after removal of voltage biases, and voltage-controlled protein patterning of casein. This material is available free of charge via the Internet at http://pubs.acs.org References (1) Zhu, H.; Snyder, M. Curr. Opin. Chem. Biol. 2003, 7, 55-63. (2) Fung, E. T.; Thulasiraman, V.; Weinberger, S. R.; Dalmasso, E. A. Curr. Opin. Biotechnol. 2001, 12, 65-69. (3) Thissen, H.; Johnson, G.; Hartley, P. G.; Kingshott, P.; Griesser, H. J. Biomater. 2006, 27, 35-43. (4) Gwynne, P.; Heebner, G. Science 2003, 302, 125-135. (5) Xu, Q.; Lam, K. S. J. Biomed. Biotechnol. 2003, 5, 257-266. (6) Hoff, J. D.; Cheng, L.-J.; Meyhofer, E.; Guo, L. J.; Hunt, A. J. Nano Lett. 2004, 4 (5), 853-857. (7) Lussi, J. W.; Tang, C.; Kuenzi, P.-A.; Staufer, U.; Csucs, G.; Vo¨ro¨s, J.; Danuser, G.; Hubbell, J. A.; Textor, M. Nanotechnology 2005, 16, 1781-1786. (8) Lee, N. Y.; Lim, J. R.; Kim, Y. S. Biosens. Bioelectron. 2006, 21 (11), 2188-2193. (9) Roth, E. A.; Xu, T.; Das, M.; Gregory, C.; Hickman, J. J.; Boland T. Biomaterials 2004, 25, 3707-3715. (10) Lee, K.-B.; Park, S.-J.; Mirkin, C. A.; Smith, J. C.; Mrksich, M. Science 2002, 295, 1702-1705. (11) Bo¨hringer, K. F.; Bilge, H.; Cheng, X.; Ratner, B.; Takeuchi, S.; Fujita, H. Infrared light induced patterning of proteins on ppNIPAM thermoresponsive thin films: a “protein laser printer”. IEEE Conference on Micro Electro Mechanical Systems (MEMS), Istanbul, Turkey, Jan 22-26, 2006. (12) Bo¨hringer, K. F. J. Micromech. Microeng. 2003, 13, S1-S10. (13) Huber, D. L.; Manginell, R. P.; Samara, M. A.; Kim, B.-I.; Bunker, B. C. Science 2003, 301, 352-354. (14) Mugele, F.; Baret, J.-C. J. Phys.: Condens. Matter 2005, 17, R705R774. (15) Blawas, A. S.; Reichert, W. M. Biomaterials 1998, 19, 595-609. (16) Jones, T. B.; Wang, K.-L.; Yao, D.-J. Langmuir 2004, 20, 28132818. (17) Cho, S. K.; Moon, H.; Kim, C.-J. J. Microelectromech. Syst. 2003, 12 (1), 70-80. (18) Ahmed, F.; Alexandridis, P.; Neelamegham, S. Langmuir. 2001, 17, 537-546. (19) Proteins at Interfaces II: Fundamentals and Applications; Horbett, T. A., Brash, J. C., Eds.; American Chemical Society: Washington, DC, 1995; pp 395-404. (20) Amiji, M.; Park, K. Biomaterials 1992, 13 (10), 682-692. (21) Green, R. J.; Davies, M. C.; Roberts, C. J.; Tendler, S. J. B. J. Biomed. Mater. Res. 1998, 42 (2), 165-71. (22) Andrade, J. D.; Hlady, V.; Wei, A. P. Pure Appl. Chem. 1992, 64 (11), 1777-1781. (23) Liang, X.; Mao, G.; Ng, K. Y. S. J. Colloid Interface Sci. 2005, 285, 360-372. (24) Kleijn, M.; Norde, W. Heterogeneous Chem. ReV. 1995, 2, 157172. (25) Quinn, A.; Sedev, R.; Ralston, J. J. Phys. Chem. B 2005, 109 (13), 6268-6275.

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