Using surface plasmon resonance (SPR) spectroscopy in the Kretschmann configuration, we followed the self-assembly of organic ultrathin films which resulted from exposure of gold surfaces to solutions of CH3(CH2) n - 1SH (n = 8, 12, 16, and 18) in ethanol and heptane. We monitored film growth in situ and continuously for up to 72 h with an overall thickness resolution of <1 Å. Film dielectric constants, necessary for accurately calculating average film thicknesses from SPR spectra, were determined unambiguously for fully formed films by comparing spectra from organic films in different solvents. In addition, we introduce a novel two-color SPR experiment with which we can obtain both film thickness and film dielectric constant without changing solvents. We studied the chain length dependent and concentration dependent kinetics of film formation in ethanol and found that there are at least three distinct kinetics steps. The kinetics of the first, most rapid, step and the third, slowest, step can be described well with Langmuir adsorption models. The kinetics of the second step are zeroth order and depend on alkanethiol chain length, concentration, and partial film thickness. The formation kinetics in heptane can be described with a single step Langmuir adsorption model. We find that films formed by continuous self-assembly in solution are always thicker than films for which the process of self-assembly has been interrupted by rinsing with neat solvents. We also present evidence that, by rinsing the partially formed film before reimmersion into thiol solution, we can change the final film thickness and structure of a hexadecanethiolate film. Our results are most consistent with a formation mechanism involving adsorption of both chemisorbed and physisorbed molecules during film formation in ethanol, with the overall formation kinetics determined by the relative solubility of the alkanethiol in the solvent.
We investigate how probe density influences hybridization for unlabeled target oligonucleotides that contain mismatched sequences or targets that access different binding locations on the immobilized probe. We find strong probe density effects influencing not only the efficiency of hybridization but also the kinetics of capture. Probe surfaces are used repeatedly, and the potentially large contributions of sample-to-sample variations in surface heterogeneity and nonspecific adsorption are addressed. Results of kinetic, equilibrium, and temperature-dependent studies, obtained using in-situ surface plasmon resonance (SPR) spectroscopy, show that hybridization for surface immobilized DNA is quite different from the well-studied solution-phase reaction. Surface hybridization depends strongly on the target sequence and probe density. Much of the data can be explained by the presence of steric crowding at high probe density; however, the behavior of mismatched sequences cannot be understood using standard models of hybridization even at the lowest density studied. In addition to unusual capture kinetics observed for the mismatched targets, we find that the binding isotherms can be fit only if a heterogeneous model is used. For mismatched targets, the Sips model adequately describes probe-target binding isotherms; for perfectly matched targets, the Langmuir model can be used.
We report a quantitative study of the kinetics of formation for a two-component tethered ssDNA monolayer film using in situ two-color surface plasmon resonance (SPR) spectroscopy. The attachment of the DNA to gold is facilitated by functionalization at the 5′ end with a thiol group connected by a hexamethylene linker (HS-C6-ssDNA). Detailed data analysis is performed by quantitative comparison of the DNA coverage versus time kinetic data obtained from SPRS with numerical solutions for the differential equations for simultaneous adsorption, desorption, and diffusion at the interface. The kinetics of adsorption of HS-C 6 -ssDNA onto bare gold as well as the kinetics of loss of HS-C 6 -ssDNA from the surface during subsequent treatment with mercaptohexanol can be understood in terms of a simple physical model and self-consistent parameters. The kinetics of HS-C 6 -ssDNA adsorption on bare gold are compared to the kinetics of hybridization of surfaceattached thiolated ssDNA with the fully complementary ssDNA in free solution and found to follow remarkably similar kinetic pathways. In contrast, the adsorption of ssDNA follows complex kinetics that cannot be modeled with a single kinetic step. That is, the presence of a thiol functionality on a 25-mer ssDNA gives rise to adsorption behavior that is clearly kinetically distinct from simple ssDNA adsorption on gold.
We demonstrate that in situ optical surface plasmon resonance spectroscopy can be used to monitor hybridization kinetics for unlabeled DNA in tethered monolayer nucleic acid films on gold in the presence of an applied electrostatic field. The dc field can enhance or retard hybridization and can also denature surfaceimmobilized DNA duplexes. Discrimination between matched and mismatched hybrids is achieved by simple adjustment of the electrode potential. Although the electric field at the interface is extremely large, the tethered single-stranded DNA thiol probes remain bound and can be reused for subsequent hybridization reactions without loss of efficiency. Only capacitive charging currents are drawn; redox reactions are avoided by maintaining the gold electrode potential within the ideally polarizable region. Because of potential-induced changes in the shape of the surface plasmon resonance curve, we account for the full curve rather than simply the shift in the resonance minimum.electrochemistry ͉ DNA hybridization ͉ DNA mismatch discrimination I ncreasing research efforts are directed toward the detection of nucleic acid interactions with immobilized oligonucleotide probes for DNA microarray applications (1, 2). Limitations of most current technologies include complex DNA immobilization procedures, the need for fluorescence or other labeling, and slow hybridization kinetics that require long incubation times. In addition, those experimental conditions that optimize DNA duplex formation often also reduce the stringency of hybridization. That is, for oligonucleotides that are sufficiently long to distinguish a particular sequence in the presence of unrelated DNA, a mismatched base pair has only a marginal effect on the stability of the duplex (3). In DNA microarray applications, mismatched hybrids lead to ''false positives.''The use of an electric field to easily control the electrostatic forces on surface-immobilized polyelectrolytes such as DNA has not yet been fully exploited as a means for improving the speed and stringency of biomolecular interactions at interfaces.In this paper, we investigate the effect of simple electrostatic charging on the interactions of surface-bound monolayer nucleic acid films with unlabeled DNA target oligonucleotides by using a combination of electrochemical control and in situ real-time surface plasmon resonance (SPR) spectroscopy detection.The monolayer DNA thiol films used in this work are tethered directly to the SPR metal sensor surface through a gold-thiol covalent attachment. Therefore, the immobilized DNA hybrids are exposed to a field gradient at the metal͞electrolyte interface on the order of 10 9 V͞m. We show that this field can be used, in a reversible manner, to increase or decrease the rate of oligonucleotide hybridization. In addition, we show that a repulsive potential preferentially denatures mismatched DNA hybrids within a few minutes, while leaving the fully complementary hybrids largely intact. This sequence selectivity in hybrid denaturation imparts an extr...
Articles you may be interested in Classification of metal-oxide bonded interactions based on local potential-and kinetic-energy densitiesReactions of Ca + , Zn + and all first-row atomic transition metal ions with O 2 are studied using guided ion beam techniques. While reactions of the ground states of Sc +, Ti + , and Y+ are exothermic, the remaining metal ions react with O 2 in endothermic processes. Analyses of these endothermic reactions provide new determinations of the M+ -0 bond energies for these eight elements. Source conditions are varied such that the contributions of excited states of the metal ions can be explicitly considered for Mn + , Co +, Ni + , and Cu +. Results (in e Y) at 0 K areDo(Ca+ -0) = 3.57 ± 0.05, DO(Cr+ -0) = 3.72 ± 0.12, DO(Mn+ -0) = 2.95 ± 0.13, DO(Fe+ -0) = 3.53 ± 0.06 (reported previously), DO(Co+ -0) = 3.32 ± 0.06, DO(Ni+-O) = 2.74 ±0.07,Do(Cu+-O) = 1.62±0.15,andDo(Zn+-O) = 1.65±0.12. These values along with literature data for neutral metal oxide bond energies and ionization energies are critically evaluated. Periodic trends in the ionic metal oxide bond energies are compared with those of the neutral metal oxides and those of other related molecules.
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