Propensity of lignin to associate: light scattering photometry study with native lignins

Many studies of lignins in solution invoke association and aggregation phenomena to explain their solution behavior (e.g., reprecipitation onto pulp fibers, condensation, etc.). Following their colloidal (apparent) molecular weights in solution as a function of time allows us to explore observable dissociation phenomena. These measurements were carried out using multiple angle laser light scattering (MALLS) photometry in the static mode. The challenges and opportunities of measuring the specific refractive index increment (dn/dC) of lignin solutions and determining the kinetics of the dissociation process were thus investigated. Hardwood and softwood representative lignins were isolated, and method for their full dissolution in THF was further developed, which then lead to accurate dn/dC values being obtained as a function of time. When coupled to additional work using light scattering static measurements and Zimm plots for the same solutions, this effort offers insight into the aggregation and ensuing dissociative events that operate within the lignin macromolecules.     

Synthesis of hydrophobic nanoparticles for real‐time lysozyme detection using surface plasmon resonance sensor

Diagnostic biomarkers such as proteins and enzymes are generally hard to detect because of the low abundance in biological fluids. To solve this problem, the advantages of surface plasmon resonance (SPR) and nanomaterial technologies have been combined. The SPR sensors are easy to prepare, no requirement of labelling and can be detected in real time. In addition, they have high specificity and sensitivity with low cost. The nanomaterials have also crucial functions such as efficiency improvement, selectivity, and sensitivity of the detection systems. In this report, an SPR‐based sensor is developed to detect lysozyme with hydrophobic poly (N‐methacryloyl‐(L)‐phenylalanine) (PMAPA) nanoparticles. The SPR sensor was first characterized by attenuated total reflection‐Fourier transform infrared, atomic force microscope, and water contact angle measurements and performed with aqueous lysozyme solutions. Various concentrations of lysozyme solution were used to calculate kinetic and affinity coefficients. The equilibrium and adsorption isotherm models of interactions between lysozyme solutions and SPR sensor were determined and the maximum reflection, association, and dissociation constants were calculated by Langmuir model as 4.87, 0.019 nM⁻¹, and 54 nM, respectively. The selectivity studies of SPR sensor were investigated with competitive agents, hemoglobin, and myoglobin. Also, the SPR sensor was used four times in adsorption/desorption/recovery cycles and results showed that, the combination of optical SPR sensor with hydrophobic ionizable PMAPA nanoparticles in one mode enabled the detection of lysozyme molecule with high accuracy, good sensivity, real‐time, label‐free, and a low‐detection limit of 0.66 nM from lysozyme solutions. Lysozyme detection in a real sample was performed by using chicken egg white to evaluate interfering molecules present in the medium.     

Novel immunoassay for carcinoembryonic antigen based on protein A-conjugated immunosensor chip by surface plasmon resonance and cyclic voltammetry

In this study, an immunosensor chip utilizing surface plasmon resonance (SPR) and cyclic voltammetry (CV) was fabricated for detecting carcinoembryonic antigen (CEA). Specifically, we applied in parallel an SPR instrument and a CV device to monitor the assembly of carcinoembryonic antibody (anti-CEA) on a protein A-conjugated surface and the subsequent ligand reaction. The immunosensor chips were constructed by various concentrations of protein A. To determine the surface characteristics of different self-assembly monolayers (SAMs), several quantitative and kinetic measurements were carried out. The extent of immobilization of anti-CEA and the immune response of anti-CEA antibody against CEA were measured using the SPR instrument and CV device. The terminal functional groups of protein A have different effects on the adsorption and covalent binding of immunoprotein depending on the steric hindrance. Through the parallel measurements, we demonstrate that SPR and CV are sensitive to measure the antigen–antibody binding capacity.     

利用表面等离子体共振仪检测黄瓜花叶病毒

目的：研究一种便捷、高效地检测黄瓜花叶病毒（CMV）的方法。方法：利用表面等离子体共振（SPR）技术检测CMV。首先用11-MUA修饰SPR金片,再用EDC／NHS活化,之后通过NHS酯基与CMV抗体结合,用BSA封闭未结合的NHS酯基。将SPR金片装入SPR仪,通入待检样品,通过折射率变化实时监测实验过程。结果：该方法检测CMV的灵敏度能够达到10ng／mL,具有良好的特异性,与同属的花生矮化病毒、番茄不孕病毒无交叉反应。结论：建立的SPR方法操作简单、灵敏度高、特异性好,是一种新的高效检测CMV的方法。     

Determination of monoenzyme- and bienzyme-stimulated precipitation by a cuvette-based surface plasmon resonance instrument.

This paper describes the use of a cuvette-based surface plasmon resonance (SPR) instrument to measure biocatalyzed precipitation reactions. Enzyme-modified SPR sensor disk forms the base of a cuvette, in which the substrate solution is added with stirring. The determination of the substrate concentration relies on the measurement of SPR angle shift (Deltatheta(SPR)) induced by the deposition of the insoluble products without involving in any electrochemical reactions. As examples, horseradish peroxidase (HRP)-modified monoenzyme SPR sensor and HRP-glucose oxidase bienzyme-layered sensor are created to determine hydrogen peroxide and glucose via the catalyzed oxidation of 4-chloro-1-naphthol (4-CN). The deposition of the oxidized 4-CN-insoluble products leads to SPR angle shifts, which are linear to H(2)O(2) and glucose in the concentration ranges of 0.067-7.24 x 10(-5) and 0.7-8.3 x 10(-4) mM, respectively. The SPR sensitivities are greater than those of nonelectrochemical quartz crystal microbalance (QCM) (the parallel results in this study) and compare favorable with those of electrochemical QCM and electrochemical SPR methods. This study opens the field for enhanced SPR measurements by using biocatalyzed precipitation as a signal amplification method.     

High throughput solution-based measurement of antibody-antigen affinity and epitope binning

Advances in human antibody discovery have allowed for the selection of hundreds of high affinity antibodies against many therapeutically relevant targets. This has necessitated the development of reproducible, high throughput analytical techniques to characterize the output from these selections. Among these characterizations, epitopic coverage and affinity are among the most critical properties for lead identification. Biolayer interferometry (BLI) is an attractive technique for epitope binning due to its speed and low antigen consumption. While surface-based methods such as BLI and surface plasmon resonance (SPR) are commonly used for affinity determinations, sensor chemistry and surface related artifacts can limit the accuracy of high affinity measurements. When comparing BLI and solution equilibrium based kinetic exclusion assays, significant differences in measured affinity (10-fold and above) were observed. KinExA direct association (k_a) rate constant measurements suggest that this is mainly caused by inaccurate k_a measurements associated with BLI related surface phenomena. Based on the kinetic exclusion assay principle used for KinExA, we developed a high throughput 96-well plate format assay, using a Meso Scale Discovery (MSD) instrument, to measure solution equilibrium affinity. This improved method combines the accuracy of solution-based methods with the throughput formerly only achievable with surface-based methods.     

Equilibrium gel permeation: a single-photon counting spectrophotometer for studies of protein interaction.

When a small column or flow cell packed with gel particles is completely saturated with a solution containing molecular species of interest, the average cross-sectional area occupied by the solute (partition cross section) is conveniently and precisely determined by direct optical scanning. For a mixture of interacting solutes this equilibrium gel permeation measurement yields the weight average of the species partition cross sections and the variation of this quantity with solute concentration permits determination of the solute interaction parameters (stoichiometry, equilibrium constants). We have developed a computer-controlled single-photon counting spectrophotometer for these measurements. The instrument exhibits high precision over a wide range of optical density. With counting times in the range of 10-1000 s the standard deviations on optical densities of protein solutions measured at 220 nm are typically 0.0006 at 1 OD, 0.002 at 2 OD, 0.005 at 4 OD. Beer's law tests show that deviations from linearity are less than these precision limits. Partition cross-section measurements for proteins can be made with an accuracy of better than 0.001 and information can be obtained with protein solutions at least as low as 1 mug/ml.     

Static and dynamic light scattering approach to the hydration of hemoglobin and its supertetramers in the presence of osmolites.

We used static and dynamic light scattering for comparing the mass (MW) and hydrodynamic radius (R(h)) of several hemoglobin systems, namely human hemoglobin, bovine hemoglobin, human hemoglobin cross-linked with a sebacyl residue, and bovine hemoglobin cross-linked with an adipoyl residue. We measured the MW and R(h) of these systems in 0.1M phosphate buffer at pH 7.0 in the absence and in the presence of either betaine or glycerol up to 1.7 molal concentrations. The 90 degrees scattering was measured with a photon counting machine equipped with a diode laser at 783 nm. The Rayleigh ratio [R(theta)] of the instrument was estimated using R(theta) = 7.19E-6 cm(-1) for toluene at 783 nm. The refractive index increment of hemoglobin solutions was measured using a laser beam at 750 nm. We estimated a value dn/dc = 0.210 cm3/g in the absence and dn/dc = 0.170 in the presence of 1.7 molal osmolites. For all systems both in liganded and unliganded form, the static light scattering data showed a 16% mass increase with increasing concentration of osmolites. The hydrodynamic radii of all investigated systems in the presence and absence of osmolites were close to 3.17 nm. Assuming a partial specific volume nu = 0.739 for hemoglobin, and using spherical geometry, the estimated average hydration volume of hemoglobin was 32.6 L/mole in the absence of osmolites. It decreased to 23.5 L/mole in the presence of 1.7 molal osmolites. Assuming that the density of water in the hydration volume is D = 1.0 g/cm3, the hydration of Hb was 0.51 gH2O/gHb, with a surface density of 0.20 molH2O/A2. The hydration decreased to 0.33 gH2O/gHb and 0.14 molH2O/A2 in the presence of 1.7 molal osmolites. The decreased hydration was compensated by the increased mass (i.e., decreased surface area per unit volume) so that the thickness of the water shell around these proteins remained close to a single layer of water molecules. These findings indicate that the combination of static and dynamic light scattering offer unique means for investigating the relevance of water activity on the structure and function of biological macromolecules. In the case of hemoglobin, the data suggest that the decreased oxygen affinity in the presence of osmolites reported by Colombo et al. (M. F. Colombo, D. C. Rau, and V. A. Parsegian Science, 1992, Vol. 256, pp. 655-659), as due to ligand linked water binding on hemoglobin surface, is part of a complex phenomenon involving the hydration shell of hemoglobin and the formation of low affinity supertetrameric molecules.     

An improved method for checking HTS/uHTS liquid-handling systems

An efficient method is presented to determine precision and accuracy of multichannel liquid-handling systems under conditions near to application. The method consists of gravimetrical determination of accuracy and optical determination of precision based on the dilution of absorbing and fluorescent dye solutions in microplates. Mean delivery volume per well can be determined with precision better than a 0.04% coefficient of variation (CV). Optical signal precision, CV(S), is improved by multiwavelength measurements. Precision of absorbance measurement yields a better resolution than precision of fluorescence measurement (0.3% and 1.5%, respectively), indicating that absorbance measurements should be preferred. From CV(S), an upper bound of the precision of the volumes delivered is derived. Method performance is demonstrated with the dispenser CyBi-Drop and the pipettor CyBi-Well using different ejection principles; with commonly used fluids; with 96-, 384-, and 1536-well microplates; and with photometric and fluorometric indicators. Precision of the volumes delivered, as obtained with optimized methods, all plate formats, and both devices, is better than 2% CV with 2 microL set volume and about 1% CV with higher set volumes.     

Evaluation of enantioselective gas chromatography for the determination of minute deviations from racemic composition of alpha-amino acids with emphasis on tyrosine: accuracy and precision of the method

Whereas the determination of high enantiomeric fractions (EF) of chiral compounds is very well established, the accurate determination of small deviations from racemic compositions has not yet received much attention despite its relevance to studies dealing with the origin of homochirality, where only small initial enantiomeric bias is expected. Racemic samples of representative alpha-amino acids were derivatized as N-(O,S)-trifluoroacetyl/ethylesters and analyzed by enantioselective gas chromatography (GC) on fused silica capillaries coated with the chiral stationary phases (CSPs) Chirasil-D-Val, Chirasil-L-Val, and Lipodex E with GC/FID and GC/MS detection. The validation (accuracy and precision) of the determination of the enantiomeric fraction EF of the D-enantiomer in racemic or near-racemic compositions for 10 DL-alpha-amino acids obtained from commercial sources has been carried out. Emphasis is given to DL-tyrosine, the enantiomers of which have recently been claimed to show different crystallization properties. Values of EF obtained from GC measurements using CSPs were compared with those from CE using chiral mobile phase additives. While the precision of the GC method is generally better than 0.08% for all DL-alpha-amino acids studied, accuracy (trueness) of determination of amino acids with polar side chains is poorer than expected from the precision as a result of systematic errors. The accuracy determined relied on measurements on two oppositely configurated CSPs.     

Surface Plasmon Resonance Studies of the Hybridization Behavior of DNA-Modified Gold Nanoparticles with Surface-Attached DNA Probes

Colloidal gold nanoparticles (AuNPs) have been extensively investigated as amplification tags to improve the sensitivity of surface plasmon resonance (SPR) biosensors. When using the so-called AuNP-enhanced SPR technique for DNA detection, the density of single-stranded DNA (ssDNA) on both the AuNPs and planar gold substrates is of crucial importance. Thus, in this work, we carried out a systematical study about the influence of surface ssDNA density onto the hybridization behavior of various DNA-modified AuNPs (DNA-AuNPs) with surface-attached DNA probes by using surface plasmon resonance spectroscopy. The lateral densities of the ssDNA on both the AuNPs and planar gold substrates were controlled by using different lengths of oligo-adenine sequence (OAS) as anchoring group. Besides SPR measurements, the amount of the captured DNA-AuNPs after the hybridization was further identified via atomic force microscope (AFM). SPR and AFM results clearly indicated that a higher ssDNA density on either the AuNPs or the gold substrates would give rise to better hybridization efficiency. Moreover, SPR data showed that the captured DNA-AuNPs could not be removed from SPR sensor surfaces using various dehybridization solutions regardless of surface ssDNA density. Consequently, it is apparent that the hybridization behavior of DNA-AuNPs was different from that of solution-phase ssDNA. Based on these data, we hypothesized that both multiple recognitions and limited accessibility might account for the hybridization of DNA-AuNPs with surface-attached ssDNA probes.

     

High-precision,high-throughput stability determinations facilitated by robotics and a semiautomated titrating fluorometer

The use of statistical modeling to test hypotheses concerning the determinants of protein structure requires stability data (e.g., the free energy of denaturation in H(2)O, DeltaG(HOH)) from hundreds of protein mutants. Fluorescence-monitored chemical denaturation provides a convenient method for high-precision, high-throughput DeltaG(HOH) determination. For eglin c we find that a throughput of about 20 min per protein can be attained in a two-channel semiautomated titrating fluorometer. We find also that the use of robotics for protein purification and preparation of the solutions for chemical denaturation gives highly precise DeltaG(HOH) values in which the standard deviation of values from multiple preparations (+/-0.051 kcal/mol) differs very little from multiple measurements from a single preparation (+/-0.040 kcal/mol). Since the variance introduced into model fitting by DeltaG(HOH) increases as the square of measurement error, there is a premium on precision. In fact, the fraction of stability behavior explicable by otherwise perfect models goes from 98% to only 50% over the error range commonly reported for chemical denaturation measurements (0.1-0.6 kcal/mol). We have found that the precision of chemical denaturation DeltaG(HOH) measurements depends most heavily on the precision of the instrument used, followed by protein purity and the capacity to precisely prepare the solutions used for titrations.     

A simple method to improve the precision and accuracy of gas-phase oxygen electrodes.

The precision and accuracy of the measurements using an oxygen gas-phase electrode thermostabilized in an ice bath were evaluated. The precision found was comparable with that obtained with the paramagnetic method and with Scholander analysis. The accuracy was comparable with that of the paramagnetic method.     

Surface plasmon resonance measurement of pH-induced responses of immobilized biomolecules: conformational change or electrostatic interaction effects?

Recently, the observation of pH-induced conformational changes of biomolecules supported on carboxymethyldextran (CMD)-coated surfaces measured using surface plasmon resonance (SPR) has been reported. However, it is apparent that the evidence reported in the literature is ambiguous. The research presented in this paper describes investigations to study the changing SPR signal of immobilized biomolecules as a function of varying pH, to provide a detailed understanding of the origin of the pH-induced changes in the SPR profile. SPR measurements were performed with cytochrome c, concanavalin A, and poly-L-lysine, biomolecules that exhibit diverse conformational responses to changing pH, covalently immobilized onto CMD-coated supports. These SPR measurements were supported by circular dichroism (CD) solution studies. The SPR profiles recorded were not consistent with the conformational transitions of the biomolecules as observed using CD. An alternative explanation for the observed shifts in SPR is proposed, which explains the SPR profiles in terms of electrostatic interaction effects between the immobilized biomolecules and the carboxymethyldextran matrix.     

Sodium and potassium ion-dependent change in oligomerization of Na,K-ATPase in C12E8 detected by low-angle laser light scattering technique in combination with high performance porous silica-gel chromatography

Approximate molecular weights and the subunit structures of Na,K-ATPase from horse kidney were estimated by means of the combination of porous silica gel chromatography, laser light scattering (LS) and refractive index (RI) measurements in C12E8. When the enzymes were eluted with NaCl- or KCl-containing solution, 3 or 4 protein peaks, respectively were detected except that of low molecular weight range. These peaks were tentatively named Na-1, Na-2, Na-2', Na-3 (NaCl-containing eluents), K-1, K-2, K-3 (KCl-containing eluents), respectively. Na,K-ATPase and K-p-nitrophenylphosphatase activities were detected at all peaks. The activities were completely inhibited by ouabain. The ratios of the output from laser light scattering to that of differential refractive index intensity for reference proteins and these peaks were compared. Relative values of refractive index increments of BSA, thyroglobulin and C12E8 measured with the same RI detector under the same conditions were 0.144, 0.141, and 0.135 respectively. The size of the enzyme at the main peak (K-2) with K eluents (KCl 10 mM, 25 mM) was twice that at the main peak (Na-2') with Na eluents (1, 25, 50 mM NaCl) assuming that dn/dc of K-2 is similar to that of Na-2'. Na-3 and K-3 appeared at the same retention time and showed the same values of LS/RI. Provided that the dn/dc values of both peaks are similar to those of Na-2' and K-2, the sizes of Na-3 and K-3 are one-third of Na-2' and one-sixth of K-2, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Efficiently measuring complex sessile epibenthic organisms using a novel photogrammetric technique

This paper describes a stereo photogrammetry method that allows accurate measurements of volume for sessile epibenthic organisms. It represents a novel approach based on multiple views (five stereo image pairs) from a purpose built stereo digital still camera system combined with a three-dimensional reconstruction software program (CAM). The bias, accuracy, precision and efficiency of the method were assessed in the laboratory using models with three levels of morphological complexity (simple, moderate and complex morphologies) and two sizes (large and small). The technique did not show any biases to observer experience, with no significant difference among observers (p > 0.05). Volume measurements made with CAM were very accurate when compared with the water displacement volume of each model, with an overall mean error of about − 3% (S.E. ± 1%). The CAM volume measurements were more accurate on complex models and moderately complex models than on models with simple morphologies. Also, large models had a higher accuracy than small models. Volume measurements made with CAM were also highly precise with the lowest precision observed being ± 2% of the volume estimate. The time required for a volume estimation using the CAM method was also highly efficient, and the longest time taken for a volume estimation was on average 1 h and 36 min, making it the fastest reported three-dimensional reconstruction method. In field applications, volume estimations of four sponges were all within the observed accuracy, precision and efficiency established during laboratory trials. The accuracy, precision and efficiency demonstrated by the CAM method make this technique highly suitable for routine measurements of the volume of sessile epibenthic organisms.     

Poly-(3-hexylthiophene) self-assembled monolayer based cholesterol biosensor using surface plasmon resonance technique

Cholesterol oxidase (ChOx) has been covalently immobilized onto 1-fluoro-2-nitro-4-azidobenzene (FNAB) modified poly-(3-hexylthiophene) (P3HT) self-assembled monolayer (SAM) onto gold coated glass plates. These ChOx/FNAB/P3HT/Au bio-electrodes have been characterized using contact angle (CA) measurements, UV-vis spectroscopy, electrochemical impedance technique, cyclic voltammetric technique and atomic force microscopic (AFM) technique, respectively. The ChOx/FNAB/P3HT/Au bio-electrodes were utilized for the estimation of cholesterol concentration in standard solutions using surface plasmon resonance (SPR) technique. It is shown that this SPR biosensor has linearity from 50 to 500 mg/dl of cholesterol in solution with detection limit of 50 mg/dl, sensitivity of 1.0 4 m degrees /(mg dl), reusability of around 15 times and a shelf-life of about 10 weeks when stored at 4 degrees C.     

Liquid phase SPR imaging experiments for biosensors applications

Surface plasmon resonance (SPR) has recently gained attention as a label-free method for the detection of biological molecules binding onto functionalised surfaces. It is one of the most sensitive detection method for monitor variations in the thickness and refractive index in ultra-thin films. Here, the adsorption processes of oligonucleotides onto gold substrates have been investigated in aqueous buffer solution using SPR imaging measurements. The hybridization of a thiol-modified, single stranded oligonucleotide anchored to a gold surface via thiol group, with its complementary sequence has been observed and characterised monitoring the hybridization process by SPR equipment. In situ investigation of smallest changes in SPR imaging measurements dynamically performed in liquid phase in the presence of DNA complementary probes was performed. Infrared spectroscopy and scanning electron microscopy characterisation of the functionalised gold surfaces of the biosensor were compared with the images obtained by SPR experimental apparatus.     

Detection of subpicomolar concentrations of human matrix metalloproteinase-2 by an optical biosensor

We describe in this paper the development of a one-step sandwich assay for the highly sensitive and fast detection of human matrix metalloproteinase (MMP)-2 (EC 3.4.24.24), using surface plasmon resonance (SPR). For the assay, two ligands were selected: monoclonal anti-MMP-2 antibody Ab-2 and the tissue inhibitor of metalloproteinases (TIMP)-2. They were chosen on the basis of (1) their affinities to MMP-2, (2) the efficiency of immobilization to the sensor chip, (3) the efficiency of adsorption to colloidal gold, and (4) the stability of these protein-coated gold particles. The assay included mixing of MMP-2 with antibody Ab-2 adsorbed to colloidal gold with a diameter of about 20nm and injection into the flowcell of the SPR instrument containing immobilized TIMP-2. By using colloidal gold particles an amplification factor of 114 and a detection limit of 0.5pM for MMP-2 were obtained. The precision of the assay was high even at low analyte concentrations, the standard deviation being 8.3% for five determinations of 1pM MMP-2. No significant binding was observed with the structurally related MMP-9. The assay is far more sensitive and faster than commonly used methods for MMP-2 detection. As TIMP-bound MMP-2 is not detected by this method, the assay can be applied for measuring free MMP-2, reflecting the imbalance of free and inhibitor-bound enzyme in various pathological situations.     

A precise water displacement method for estimating egg volume

ABSTRACT.   Relationships between egg volume and an array of life-history traits have been identified for many bird species. Despite the importance of egg volume and the need for precise and accurate measurements, egg volume is usually estimated using a mathematical model that incorporates length and width measurements along with a shape variable. We developed an instrument that provides precise estimates of egg volume and can be easily used in the field. Using Clapper Rail ( Rallus longirostris ) eggs, we compared egg volumes measured using our instrument with estimates based on linear measurements. We found our instrument to be both precise and accurate. Compared with a method based on linear measurements of eggs, use of our instrument reduced variation in egg volume estimates by 1.6 cm³, approximately 8% of the volume of a Clapper Rail's egg. Further advantages of our technique include ease of use, increased accuracy of field-based volume estimates, and increased resolution of variation in egg volume estimates. In addition, our technique does not require postdata collection processing time and did not influence hatching success. Also, for Clapper Rails and similar species, our technique can be combined with other techniques (e.g., egg flotation) so that both egg volume and embryonic stage can be estimated at the same time.