Site-selective lateral multilayer assembly of bienzyme with polyelectrolyte on ITO electrode based on electric field-induced directly layer-by-layer deposition

We describe here a new approach to construct a multilayer enzyme/polyelectrolyte film on a structured transparent indium-tin oxide (ITO) covered glass electrode surface as micropattern, on which two different types of enzyme distributed laterally on one common substrate without interference. The multilayer film was prepared by alternate electric field directed layer-by-layer assembly deposition and alternate deposition of different redox enzymes and polyelectrolyte poly(diallyldimethylammonium chloride) (PDDA) onto the site-selective ITO glass electrode surface. The cyclic voltammogram, obtained from the ITO glass electrode modified with the glucose oxidase (GO(X))/PDDA and catalase (CA(T))/PDDA multilayers, revealed that the bioelectrocatalytic response is directly correlated to the number of deposition bilayers. From the analysis of cyclic voltammetric characterization, the coverage of catalytically active enzymes per enzyme/PDDA bilayer during the multilayer formation was homogeneous, which demonstrates that the multilayer is constructed in a spatially ordered manner. Also, from the atomic force microscopy and Brewster angle microscopy measurements, more information of the multilayer constructed by different methods on the modified electrode surface is obtained and compared. This fabrication technique is simple and would be applicable to the construction of a thickness- and area-controlled biopattern composed of multi-enzymes as well as multiple biomaterials.     

Electrochemical Behaviour of Copper-Containing Nitrite Reductase from Alcaligenes Faecalis Strain-6

Indirect and direct electrochemical reactions of copper containing nitrite reductase (NIR) from Alcaligenes faecalis strain-6 are described. The reactivity of mediators, including blue protein from the same organism (the native redox partner of NIR, AfBP), in electrocatalytic reactions (EC') involving a mediator, NIR and nitrite was investigated. Several types of EC were observed and AfBP was found to be an effective mediator in spite of its high redox potential. Direct electrochemistry was observed at an Indium Tin Oxide electrode (ITO) and an edge plane oriented pyrolytic graphite electrode (PGE). Observation of the redox activity of NIR at an ITO in an optically transparent thin layer electrode cell (OTTLE) showed that it underwent reversible changes in absorbance that corresponded to the applied potential. The electrochemically adsorbed NIR at PGE showed fast electrochemical kinetics in cyclic voltammetry. It is suggested that the weak affinity of NIR to the PGE electrode may prevent complete denaturation of NIR in the adsorbed state.     

An endothelial cell compatible biosensor fabricated using optically thin indium tin oxide silicon nitride electrodes

This study describes the fabrication and performance of an endothelial cell compatible, optically thin, indium tin oxide (ITO) microimpedance biosensor. The biosensor was constructed by sputtering a thin insulating layer of silicon nitride (Si(3)N(4)) onto a 100 nm thick ITO layer. Indium tin oxide electrodes were formed by chemically etching 250 or 500 microm diameter holes through the Si(3)N(4) insulating layer. The exposed ITO electrode was electrically connected to an ITO counter electrode, approximately 2 cm(2) in area, via a 400 microL well containing cell culture media. A lock-in amplifier circuit monitored the impedance of porcine pulmonary artery endothelial cells (PPAECs) cultivated on the electrodes as a function of frequency, between 10 and 100 kHz, and as a function of time, at 5.62 kHz. The ITO-Si(3)N(4) microelectrodes provided consistent and repeatable impedance measurements to the attachment and spreading of PPAECs. In addition, the ITO-Si(3)N(4) electrodes were recyclable, robust, resistant to ethanol sterilization, and had a high optical transmittance. Most importantly, the ITO-Si(3)N(4) electrodes allowed optical access for dynamic cellular attachment imaging. The 5.62 kHz time dependent cellular impedance response to the drug Cytochalasin D further demonstrated the feasibility of using this electrode configuration for dynamic cellular impedance studies.     

Cholesterol biosensors prepared by layer-by-layer technique

The analysis of formation, deposition and characterization of cholesterol oxidase (COX) layer-by-layer films were performed. Initially, a layer of polyanion, poly(styrene sulfonate) (PSS) was adsorbed followed by a layer of polycation, poly(ethylene imine) (PEI) on each solid substrate from aqueous solutions. The alternating layers were formed by consecutive adsorption of polycations (PEI) and negatively charged proteins (COX) and cholesterol esterase (CE). A strong interaction between protein and polyelectrolyte improves the stability of the alternating multilayer; however, it can change a native protein conformation and impair the protein activity. The PSS/PEI/COX, PSS/PEI/COX/PEI/CE, PSS/PEI/COX-CE/PEI etc. layered structures were prepared on the surface of a platinum electrode, ITO coated glass plate, quartz crystal microbalance, quartz plates, mica and silicon substrates. Optical and gravimetric measurements based on an ultraviolet–visible absorption spectroscopy and a quartz crystal microbalance revealed that the enzyme multilayers thus prepared consist of molecular layered of the proteins. The surface morphology of such bilayer films was investigated by using atomic force microscopy. The electrochemical redox processes of the enzyme-layered films deposited either on platinum or ITO coated glass plate were investigated. The response current of cholesterol oxidase electrode with concentration of cholesterol was investigated at length.     

AFM and impedance spectroscopy characterization of the immobilization of antibodies on indium-tin oxide electrode through self-assembled monolayer of epoxysilane and their capture of Escherichia coli O157:H7

The microscopic surface molecular structures and macroscopic electrochemical impedance properties of the epoxysilane monolayer and anti-Escherichia coli antibody layer on an indium-tin oxide (ITO) electrode surface were studied in this paper. Characterization of stepwise changes in microscopic features of the surfaces and electrochemical properties upon the formation of each layer were carried out using both atomic force microscopy (AFM) and electrochemical impedance spectroscopy in the presence of [Fe(CN)6](3-/4-) as a redox couple. AFM images of the self-assembled monolayer (SAM) evidenced the dense, complete, and homogeneous morphology of the epoxysilane monolayer on the ITO surface. The uniformity of the epoxysilane SAM allowed antibodies to attach to the epoxy surface groups of the silanes in a similarly uniform fashion. The effects of epoxysilane monolayer and the antibody layer on the electrochemical properties of the electrode were quantitatively analyzed in terms of double layer capacitance, electron transfer resistance, Warburg impedance and solution resistance using Randles model as the equivalent circuit. It was demonstrated that the epoxysilane monolayer and the antibody layer act as barriers for the electron transfer between the electrode surface and the redox species in the solution, resulting in most significant increases in the electron transfer resistance compared to all the electric elements. Immunoreaction with E. coli O157:H7 cells demonstrated specific recognition of the immobilized anti-E. coli antibodies as evidenced by AFM imaging and impedance spectroscopy. It was found that the binding of E. coli cells mainly affected the electron transfer resistance and Warburg impedance.     

Efficient Polymer Solar Cells on Opaque Substrates with a Laminated PEDOT:PSS Top Electrode

Solution processed polymer:fullerene solar cells on opaque substrates have been fabricated in conventional and inverted device configurations. Opaque substrates, such as insulated steel and metal covered glass, require a transparent conducting top electrode. We demonstrate that a high conducting (900 S cm^?1) PEDOT:PSS layer, deposited by a stamp‐transfer lamination technique using a PDMS stamp, in combination with an Ag grid electrode provides a proficient and versatile transparent top contact. Lamination of large size PEDOT:PSS films has been achieved on variety of surfaces resulting in ITO‐free solar cells. Power conversion efficiencies of 2.1% and 3.1% have been achieved for P3HT:PCBM layers in inverted and conventional polarity configurations, respectively. The power conversion efficiency is similar to conventional glass/ITO‐based solar cells. The high fill factor (65%) and the unaffected open‐circuit voltage that are consistently obtained in thick active layer inverted geometry devices, demonstrate that the laminated PEDOT:PSS top electrodes provide no significant potential or resistive losses.     

Upscaling of Perovskite Solar Cells: Fully Ambient Roll Processing of Flexible Perovskite Solar Cells with Printed Back Electrodes

A scaling effort on perovskite solar cells is presented where the device manufacture is progressed onto flexible substrates using scalable techniques such as slot‐die roll coating under ambient conditions. The printing of the back electrode using both carbon and silver is essential to the scaling effort. Both normal and inverted device geometries are explored and it is found that the formation of the correct morphology for the perovskite layer depends heavily on the surface upon which it is coated and this has significant implications for manufacture. The time it takes to form the desired layer morphology falls in the range of 5–45 min depending on the perovskite precursor, where the former timescale is compatible with mass production and the latter is best suited for laboratory work. A significant loss in solar cell performance of around 50% is found when progressing to using a fully scalable fabrication process, which is comparable to what is observed for other printable solar cell technologies such as polymer solar cells. The power conversion efficiency (PCE) for devices processed using spin coating on indium tin oxide (ITO)‐glass with evaporated back electrode yields a PCE of 9.4%. The same device type and active area realized using slot‐die coating on flexible ITO‐polyethyleneterphthalate (PET) with a printed back electrode gives a PCE of 4.9%.     

An Electrode Design Rule for Organic Photovoltaics Elucidated Using Molecular Nanolayers

Silane nanolayers deposited from the vapor phase onto indium‐tin oxide (ITO) coated glass are shown to be an effective means of tuning the work function and stabilizing the surface of this complex ternary oxide. Using this approach a pair of model hole‐extracting electrodes have been developed to investigate how the performance of bi‐layer organic photovoltaics is impacted by built‐in positive space charge in the critical region close to the hole‐extracting electrode. The magnitude and spatial distribution of positive space charge resulting from ground‐state electron transfer from the donor layer to the ITO electrode upon contact formation, is derived from direct measurements of the interfacial energetics using the Kelvin probe technique. This judiciously designed experiment shows that it is unnecessary to engineer the work function of the hole‐extracting electrode to match the ionization potential of the donor layer, rather only to ensure that the former exceeds the latter, thus simplifying an important aspect of device design. In addition, it is shown that silane nanolayers at the ITO electrode surface are remarkably effective at retarding device degradation under continuous illumination.     

Improvement of Transparent Metal Top Electrodes for Organic Solar Cells by Introducing a High Surface Energy Seed Layer

We present highly transparent and conductive silver thin films in a thermally evaporated dielectric/metal/dielectric (DMD) multilayer architecture as top electrode for efficient small molecule organic solar cells. DMD electrodes are frequently used for optoelectronic devices and exhibit excellent optical and electrical properties. Here, we show that ultrathin seed layers such as calcium, aluminum, and gold of only 1 nm thickness strongly influence the morphology of the subsequently deposited silver layer used as electrode. The wetting of silver on the substrate is significantly improved with increasing surface energy of the seed material resulting in enhanced optical and electrical properties. Typically thermally evaporated silver on a dielectric material forms rough and granular layers which are not closed and not conductive below thicknesses of 10 nm. With gold acting as seed layer, the silver electrode forms a continuous, smooth, conductive layer down to a silver thickness of 3 nm. At 7 nm silver thickness such an electrode exhibits a sheet resistance of 19 Ω/□ and a peak transmittance of 83% at 580 nm wavelength, both superior compared to silver electrodes without seed layer and even to indium tin oxide (ITO). Top‐illuminated solar cells using gold/silver double layer electrodes achieve power conversion efficiencies of 4.7%, which is equal to 4.6% observed in bottom‐illuminated reference devices employing conventional ITO. The top electrodes investigated here exhibit promising properties for semitransparent solar cells or devices fabricated on opaque substrates.     

Oxidation-reduction potential of the ferro-ferricyanide system in buffer solutions

The redox potential (E₀′) of the potassium ferrocyanide-potassium ferricyanide oxidation-reduction potential buffer was measured in four pH buffer solutions, acetate, Tris, phosphate, and borate, under specified conditions of pH, solution composition, and temperature. The potentials reported should be accurate, on the hydrogen electrode scale, to within about 2 mV and precise to within at least ±0.3 mV. Although the potential of the ferro-ferricyanide couple is sensitive to fairly small changes in experimental conditions, several methods are discussed by which this potential can be estimated with a reasonable degree of accuracy (about 2–10 mV) in solutions which differ somewhat from the particular solutions reported here. Attention is called to the need for greater care in specifying experimental conditions in the determination of redox potentials of various biological species.     

A Systematic Investigation of Differential Effects of Cell Culture Substrates on the Extent of Artifacts in Single-Molecule Tracking

Single-molecule techniques are being increasingly applied to biomedical investigation, notwithstanding the numerous challenges they pose in terms of signal-to-noise ratio issues. Non-specific binding of probes to glass substrates, in particular, can produce experimental artifacts due to spurious molecules on glass, which can be particularly deleterious in live-cell tracking experiments. In order to resolve the issue of non-specific probe binding to substrates, we performed systematic testing of a range of available surface coatings, using three different proteins, and then extended our assessment to the ability of these coatings to foster cell growth and retain non-adhesive properties. Linear PEG, a passivating agent commonly used both in immobilized-molecule single-molecule techniques and in tissue engineering, is able to both successfully repel non-specific adhesion of fluorescent probes and to foster cell growth when functionalized with appropriate adhesive peptides. Linear PEG treatment results in a significant reduction of tracking artifacts in EGFR tracking with Affibody ligands on a cell line expressing EGFR-eGFP. The findings reported herein could be beneficial to a large number of experimental situations where single-molecule or single-particle precision is required.     

Lithographic techniques and surface chemistries for the fabrication of PEG-passivated protein microarrays

This article presents a new technique to fabricate patterns of functional molecules surrounded by a coating of the inert poly(ethylene glycol) (PEG) on glass slides for applications in protein microarray technology. The chief advantages of this technique are that it is based entirely on standard lithography processes, makes use of glass slides employing surface chemistries that are standard in the microarray community, and has the potential to massively scale up the density of microarray spots. It is shown that proteins and antibodies can be made to self-assemble on the functional patterns in a microarray format, with the PEG coating acting as an effective passivating agent to prevent non-specific protein adsorption. Various standard surface chemistries such as aldehyde, epoxy and amine are explored for the functional layer, and it is conclusively demonstrated that only an amine-terminated surface satisfies all the process constraints imposed by the lithography process sequence. The effectiveness of this microarray technology is demonstrated by patterning fluorescent streptavidin and a fluorescent secondary antibody using the well-known and highly specific interaction between biotin and streptavidin.     

A novel hydrogen peroxide biosensor based on the immobilization of hemoglobin on three-dimensionally ordered macroporous (3DOM) gold-nanoparticle-doped titanium dioxide (GTD) film

The three-dimensionally ordered macroporous gold-nanoparticle-doped titanium dioxide (3DOM GTD) film was modified on the indium-tin oxide (ITO) electrode surface. Hemoglobin (Hb) has been successfully immobilized on the 3DOM GTD film and the fabrication process was characterized by Raman and UV-vis spectra. The results indicated that the Hb immobilized on the film retained its biological activity and the secondary structure of Hb was not destroyed. The direct electrochemistry and electrocatalysis of Hb immobilized on this film have been investigated. The Hb/3DOM GTD/ITO electrode exhibited two couples of redox peaks corresponding to the Hb intercalated in the mesopores and adsorbed on the external surface of the film with the formal potential of -0.20 and -0.48 V in 0.1M PBS (pH7.0), respectively. The Hb/3DOM GTD/ITO electrode exhibits an excellent eletrocatalytic activity, a wide linear range for H(2)O(2) from 5.0 μM to 1.0mM with a limit of detection of 0.6μM, high sensitivity (144.5 μA mM(-1)), good stability and reproducibility. Compared with the TiO(2) nanoneedles modified electrode, the GTD modified electrode has higher sensitivity and response peak current. The 3DOM GTD provided a good matrix for bioactive molecules immobilization, suggesting it has the potential use in the fields of H(2)O(2) biosensors.     

A high-potential redox component located within cyanobacterial photosystem II.

The calcium-dependent oxygen evolution activity of preparations of Phormidium luridum shows a marked selectivity in favor of ferricyanide over benzoquinone as Hill oxidant. In addition, the rate of oxygen evolution increases with increasing solution redox potential over the range +350 to +550 mV vs. the standard hydrogen electrode. These properties pertain to both 3-(3,4-dichlorophenyl)-1,1-dimethylurea-sensitive and -insensitive fractions of the total oxygen evolution activity. Neither changes in solution potential nor use of oxidants other than ferricyanide obviate the need for added Ca(2+). To explain these observations, two models are proposed, each of which invokes the existence of a redox component located within Photosystem II and having a midpoint potential greater than +450 mV. In one model, the postulated species is a donor which competes with water for oxidizing equivalents generated by System II. In the other model, the 450 mV species is a high-potential primary acceptor of System II electrons.     

Electrochemical properties of Na+- and K+-selective glass microelectrodes.

Electrochemical properties of Na+-selective glass microelectrodes were studied and compared with those of K+-selective glass microelectrodes. The selectivity of Na+-selective glass microelectrodes depended on the ion concentration of test solutions. With aging, resistance of Na+-selective microelectrodes increased and their selectivity for Na over K decreased. Na+-selective microelectrodes potential measured in NaCl solution remained constant with aging, while the potential measured in KCl solution decreased and became more positive. The changes in resistance and potential of Na+-selective microelectrodes may be due to the effects of the less mobile cation, i.e., H+ or K+ on the Na ion exchange in the Na-sensing region. The results indicate that Na+-selective microelectrodes must be used as soon after filling as possible. The selectivity of Na+-selective microelectrodes increased with increase of the sensitive exposed-tip length, whereas their response time became slow due to a large recessed volume, indicating requirement of an optimum exposed-tip length for intracellular applications. The changes in the properties of Na+-selective glass microelectrodes with aging contrasted with those of K+-selective glass microelectrodes in which resistance decreased and K+-selectivity increased. The K+-selective microelectrodes required aging before use for a high selectivity and low resistance. The K+-selective microelectrodes with low resistance after sufficient aging can be used without insulation to measure K+ and Na+ activities in aqueous solutions. The different properties between Na+- and K+-selective microelectrodes are understandable, because hydration of N+-selective glass is much less extensive than that of K+-selective glass.     

Monitoring of cell growth and assessment of cytotoxicity using electrochemical impedance spectroscopy

Electrochemical impedance spectroscopy (EIS) was used to monitor the growth of mammalian cancer cells and evaluate the cytotoxicity of chemicals using Fe(CN)6(3-/4-) as a redox probe. Cancer cells, the human hepatocarcinoma cell line (BEL7404), were grown on optically transparent indium tin oxide (ITO) semiconductor slides, which were used as the working electrodes in electrochemical experiments. Attachment and proliferation of cancer cells on ITO surfaces resulted in increase of electron-transfer resistance (R(et)) between the redox probe of Fe(CN)6(3-/4-) in electrolyte solution and ITO electrode surface. For cytotoxicity assessment, cells grown on ITO substrates were further cultured in the presence of different cytotoxicants and electrochemical impedance measurements were carried out at different time intervals. Gemcitabine, a promising antineoplastic drug showing activity against a wide spectrum of human solid tumors, was selected as a model for long-term cytotoxicity effect study, whereas mercury chloride represented a model for acute toxicants. The inhibitions of gemcitabine and mercury chloride on the viability and proliferation of BEL7404 cells were observed from the electrochemical impedance experiments, and the different action modes were discriminated. Additionally, microscope images were also used to observe the effects of these two chemicals on the morphology of the cells. General consistency has been found between the electrochemical impedance response and the morphological observation. Such an impedance method provides a simple and inexpensive way for in vitro assessment of chemical cytotoxicity.     

Micropatterning and Alignment of Skeletal Muscle Myoblasts Using Microflowed Plasma Process

ObjectivesThe primary objective of the study was to optimize micropatterning environments using the microchannel flowed plasma process for controlling the orientation and behaviour of skeletal muscle cells. We have studied the cellular patterning and alignment of skeletal myoblast cells on the various micropattern widths developed on glass substrates.Materials and MethodsIn this method, we have utilized the microchannel flowed plasma process to create micropatterned self-assembled monolayers of octadecyltrichlorosilane and 3-aminopropyltrichlorosilane for creating cell adhesive widths of 20, 200 and 1000 microns on the glass substrates. The micropatterned substrates were characterized by using fluorescein 5(6)-isothiocyanate. Thereafter, the substrates were used to culture and pattern C2C12 and primary rat skeletal muscle cells. Further, we have studied the spatiotemporal variation in the orientation of the cells by using bright field and fluorescence microscopy. The microscopic images were analysed by using orientation order parameter and orientation distribution analysis.ResultsFITC based characterization of micropatterns reveals that the adopted process for micropatterning can effectively create cell adhesive widths with dimensions comparable to the diameter of myofiber. Microscopic observations and the orientation order parameter analysis reveal the precise alignment and specific orientation of myoblasts along the designated cell adhesive widths that closely mimics the physiological scenario. Both the cells showed immediate alignment within smaller cell adhesive widths of 20 and 200 μm. Actin cytoskeletal staining and its orientation distribution analysis of micropattrned C2C12 cells emphasises the influence of micropatterned environment on cytoskeletal actin orientation.ConclusionThis study corroborates the alignment of the myoblasts using surface cues facilitated by changing surface chemistry of the glass substrates. The study promotes the application of a simple micropatterning technique as a useful tool to regulate the orientation and behaviour of skeletal muscle cells. Also, the study emphasizes the role of spatial topography created by surface modification and its effect on cell adhesion and communication of alignment information across the micropatterns. The microchannel flowed plasma process could be applied to selectively pattern different adherent cell types, which could prove to be a useful platform for the exploration of various cellular processes.     

Nanowire‐Based Three‐Dimensional Transparent Conducting Oxide Electrodes for Extremely Fast Charge Collection

A 3D transparent conducting oxide (3D‐TCO) has been fabricated by growing Sn‐doped indium oxide (ITO) nanowire arrays on glass substrates via a vapor transport method. The 3D TCO charge‐collection properties have been compared to those of conventional two‐dimensional TCO (2D‐TCO) thin films. For use as a photoelectrode in dye‐sensitized solar cells, ITO‐TiO₂ core‐shell nanowire arrays were prepared by depositing a 45 nm‐thick mesoporous TiO₂ shell layer consisting of ～6 nm anatase nanoparticles using TiCl₄ treatments. Dye‐sensitized solar cells fabricated using these ITO‐TiO₂ core‐shell nanowire arrays show extremely fast charge collection owing to the shorter electron paths across the 45 nm‐thick TiO₂ shell compared to the 2D TCO. Interestingly, the charge‐collection time does not increase with the overall electrode thickness, which is counterintuitive to conventional diffusion models. This result implies that, in principle, maximum light harvesting can be achieved without hindering the charge collection. The proposed new 3D TCO should also be attractive for other photovoltaic applications where the active layer thickness is limited by poor charge collection.     

Tunable cell-surface mimetics as engineered cell substrates

Most recent breakthroughs in understanding cell adhesion, cell migration, and cellular mechanosensitivity have been made possible by the development of engineered cell substrates of well-defined surface properties. Traditionally, these substrates mimic the extracellular matrix (ECM) environment by the use of ligand-functionalized polymeric gels of adjustable stiffness. However, such ECM mimetics are limited in their ability to replicate the rich dynamics found at cell-cell contacts. This review focuses on the application of cell surface mimetics, which are better suited for the analysis of cell adhesion, cell migration, and cellular mechanosensitivity across cell-cell interfaces. Functionalized supported lipid bilayer systems were first introduced as biomembrane-mimicking substrates to study processes of adhesion maturation during adhesion of functionalized vesicles (cell-free assay) and plated cells. However, while able to capture adhesion processes, the fluid lipid bilayer of such a relatively simple planar model membrane prevents adhering cells from transducing contractile forces to the underlying solid, making studies of cell migration and cellular mechanosensitivity largely impractical. Therefore, the main focus of this review is on polymer-tethered lipid bilayer architectures as biomembrane-mimicking cell substrate. Unlike supported lipid bilayers, these polymer-lipid composite materials enable the free assembly of linkers into linker clusters at cellular contacts without hindering cell spreading and migration and allow the controlled regulation of mechanical properties, enabling studies of cellular mechanosensitivity. The various polymer-tethered lipid bilayer architectures and their complementary properties as cell substrates are discussed.     

Ultrathin functional star PEG coatings for DNA microarrays

In this study, star PEG coatings on glass substrates have been used as support material for oligonucleotide microarrays. These coatings are prepared from solutions of six armed star shaped prepolymers that carry reactive isocyanate endgroups. As described earlier, such films prevent the adsorption of proteins and the adhesion of cells but can easily be functionalized for specific biological recognition. Here we used the high functionality of these coatings for the covalent immobilization of amino terminated 20mer oligonucleotides, both by microcontact printing and spotting techniques. The permanent immobilization of fluorescently labeled DNA as well as hybridization of 20mer oligonucleotides have been monitored by fluorescence microscopy. The hybridization efficiency as determined by fluorescence intensity varied from 30% to 80% depending on the way of layer preparation. The direct spotting without additional activation and blocking steps of the surface demonstrates the potential of star PEG coatings as ultrathin surface modification for microarrays.