PEG Binding Research Articles

Complexation of Poly(ethylene glycol)-(ds)OligoDNA Conjugates with Ionic Liquids.

We report the complexation of poly(ethylene glycol) conjugated double-stranded oligoDNA (PEG-(ds)oligoDNA) with imidazolium-based ionic liquids (ILs) to form polyelectrolyte complex aggregates (PCAs). The PEG-(ds)oligoDNA conjugates are prepared following a solution-phase coupling reaction. The binding of PEG-(ds)oligoDNA with either 1-butyl-3-methylimidazolium tetrafluoroborate ([BMIM][BF4]) or 1-hexyl-3-methylimidazolium tetrafluoroborate ([HMIM][BF4]) is confirmed by a fluorescence displacement assay. Both ILs show stronger binding affinity to PEG-(ds)oligoDNA than bare (ds)oligoDNA due to the PEG-assisted increase in IL cation concentration in the vicinity of (ds)oligoDNA. The complex morphology formed at various amine (N) to phosphate (P) ratios is also examined. At high N/P ratios above 4, nanosized PCAs are formed, driven by a counterion-mediated attraction among the IL-bound (ds)oligoDNA segments and stabilized by the conjugated PEG segments. The PCAs exhibit near-neutral surface charges and resistance to DNase degradation, suggesting their potential use in gene delivery applications.

Analysis of the sustained release ability of bevacizumab-loaded tetra-PEG gel

Multiple intravitreal injections, which are painful and costly, are often required in the treatment of retinal disorders. Therefore, a novel drug delivery system using hydrogels is currently being evaluated as an alternative. This study aimed to evaluate the ability of tetra-armed polyethylene glycol (tetra-PEG) gel for sustained release in vitro. Bevacizumab-loaded tetra-PEG gel and 5-Carboxyfluorescein N-succinimidyl ester (FAM-NHS)-labeled IgG-loaded tetra-PEG gel were prepared by mixing tetra-PEG with thiol termini (tetra-PEG-SH) solution, maleimide termini (tetra-PEG-MA) solution, and bevacizumab or FAM-NHS labeled IgG. The gels were prepared with three different polymer concentrations of 1.5%, 5%, and 10%, then an in vitro release study performed to assess the sustained release ability of the drug-loaded tetra-PEG gels. High performance liquid chromatography (HPLC) was used to test the structural stability of the bevacizumab released from the tetra-PEG gel. The binding of bevacizumab to tetra-PEG-SH or MA was assessed using SDS-polyacrylamide gel electrophoresis (PAGE). The bioactivity of released bevacizumab was tested using KDR/NFAT-RE HEK293 cells. In addition, in vitro degradation and swelling studies were also performed. The in vitro release analysis showed that the release of bevacizumab was slower in the 5% and 10% tetra-PEG gels than that of 1.5% tetra-PEG gels. Similarly, the release of FAM-NHS-labeled IgG was slowest in the 1.5%, 5%, and 10% tetra-PEG gels, in that order. The 5% and 10% tetra-PEG gels released bevacizumab and FAM-NHS-labeled IgG over a period of 1–2 weeks. Both bevacizumab and FAM-NHS-labeled IgG were not fully released in 2 weeks. HPLC analysis showed that the retention time of the samples released from the bevacizumab-loaded tetra-PEG gel was similar to that of the bevacizumab standard. The SDS-PAGE analysis showed that bevacizumab binds to tetra-PEG-MA. The bioactivity assay test revealed no decrease in the bioactivity of the released bevacizumab. In vitro degradation and swelling studies revealed that 1.5%, 5%, and 10% tetra-PEG gels expanded by approximately 1.4-, 2-, and 3-fold, respectively. Based on the results of the release and swelling tests, 5% tetra-PEG gels are considered good candidates for controlled release systems for therapeutic antibodies such as bevacizumab. The binding of PEG to the therapeutic antibodies may reduce the availability of therapeutic antibodies that can be released.

Density, viscosity, excess properties, and spectral analyses of polyethylene glycol 300 and 1,3-propane diamine binary system

ABSTRACT This work reported the fundamental density (ρ) and viscosity (η) data of polyethylene glycol 300 (PEG) (1) + 1,3-propane diamine (DAP) (2) binary system at T = (293.15 to 318.15) K and atmospheric pressure, in which excess-molar volume () of the binary system presented the lowest values when x1 was at 0.5. Concurrently, the η values increased firstly and diminished in the same composition range; when x1 was at 0.7, the η values of the binary system arrived at the largest values; and the smallest and largest viscosity deviation () values of binary system were found at x1 ≈ 0.1 and x1 ≈ 0.6, respectively. Additionally, UV-Vis, FLS, 1H-NMR and Raman spectral results suggested that there was hydrogen bonding of ‘hydrogen atom in -OH groups of PEG binding nitrogen atom in -NH2 groups of DAP to form the hydrogen bonds of N···H-O’.

Inhibition of SARS-CoV-2 Spike Protein Function by Amphiphilic Block Copolymers

SARS-CoV-2 has spread across the world, creating a lethal pandemic and global crisis. Amphiphilic block-copolymers, like most poloxamers, are surfactants that attach to hydrophobic surfaces when they are in aqueous solution. Many viral proteins, such as the Coronavirus Spike Protein (SP), have hydrophobic domains exposed to the surrounding aqueous environment. Surfactants can adhere to those domains and prevent viral entry into the cell. This mode of antiviral therapy does not depend on the immune system nor would its efficacy be affected by viral mutation. These molecular simulation studies were motivated by very positive results from SARS-CoV-2 in vitro studies where large molecular weight copolymers inhibited viral replication. P188, P108, and PEG binding to the SP were investigated using molecular modeling simulations (GROMACS version 2020.3). the SARS-CoV-2 SP (QHD43416) was downloaded from the Zhang Lab at University of Michigan. Polymers were created using Assemble!. A United-Atom force field was adapted from the GROMOS 53A6 force field to account for experimentally observed behavior of α,w-dimethoxypolyethylene glycol in aqueous solutions. Binding affinities were calculated using the MM/PBSA method. The simulations were conducted at physiological conditions for a minimum of 4 ns. To understand the interactions between the copolymers and SP, the radius of gyration (Rg), root mean square deviance (RMSD), binding energies, and root mean square fluctuations (RMSF) were calculated. The Rg decreased when P188 was added to the SP, and visually, P188 attached to Regional Binding Domain (RBD) of the S1 subunit, which is responsible for specifically recognizing the ACE2 in human host cells as its receptor. These changes were not observed in P108 or PEG. The quantitative and qualitative results suggest that by binding to the RBD, P188 can inhibit viral fusion to the membranes of host cells.

Anti-PEG scFv corona ameliorates accelerated blood clearance phenomenon of PEGylated nanomedicines

Anti-PEG antibodies have been witnessed in patients and experimental animals, accelerating the blood clearance (termed ABC phenomenon) of PEGylated nanomedicines by activating complement after absorption on the nano-surface. The ABC phenomenon presents an obstacle to the clinical translation of PEGylated nanomedicines. Herein, an anti-PEG single-chain variable fragment (PEG-scFv) that possesses a low molecule weight (30 kDa) and high PEG binding affinity was exploited to ameliorate the ABC phenomenon of PEGylated liposomes (sLip). Pre-deposition of PEG-scFv on the surface of sLip was incompetent to activate complement due to the lack of Fc chains, exhibiting negligible influence on in vivo performance of sLip in naïve rats (without anti-PEG antibodies). However, PEG-scFv effectively competed the binding of anti-PEG IgM in rats that were pre-stimulated with low dose of sLip, thus ameliorated the ABC phenomenon of sLip. PEG- scFv was also effective to inhibit the binding of anti-PEG antibodies with sLip in human plasma and the consequent complement activation, presenting a promising tool to improve the performance of PEGylated nanomedicines and to mitigate individual difference occurred by the varying levels of anti-PEG antibodies in the clinic. The application of anti-PEG scFv paves a new avenue for the development of nanocarriers to achieve precise medication.

Poly(Ethylene Glycol) Interacts with Hyaluronan in Aqueous Media.

We report here the first evidence for the interaction of poly(ethylene glycol) (PEG) with hyaluronan (HA) in aqueous solutions. PEG-HA complexes (Kapp = 45,000 ± 8000 M-1) contained about 3.3 ± 0.1 of ethylene glycol units per disaccharide of HA. The carboxyl of the D-glucuronic acid and the amide of the N-acetyl-D-glucosamine did not participate in PEG binding. Similar experiments performed with dextran and monosaccharides showed that multiple free primary hydroxyls regularly distributed along the polysaccharide chain are necessary for PEG binding. Another novelty of our study is contraction of HA upon PEG binding. The effect was observed with HA in solution or adsorbed on positively charged liposomes. The thickness of the HA layer on the liposomes decreased 2-fold upon PEG addition. HA compaction induced by PEG may underlie the changes in the plasma membrane properties and resealing of mechanical injuries induced by Pluronics.

Structural basis of polyethylene glycol recognition by antibody

BackgroundPolyethylene glycol (PEG) is widely used in industry and medicine. Anti-PEG antibodies have been developed for characterizing PEGylated drugs and other applications. However, the underlying mechanism for specific PEG binding has not been elucidated.MethodsThe Fab of two cognate anti-PEG antibodies 3.3 and 2B5 were each crystallized in complex with PEG, and their structures were determined by X-ray diffraction. The PEG-Fab interactions in these two crystals were analyzed and compared with those in a PEG-containing crystal of an unrelated anti-hemagglutinin 32D6-Fab. The PEG-binding stoichiometry was examined by using analytical ultracentrifuge (AUC).ResultsA common PEG-binding mode to 3.3 and 2B5 is seen with an S-shaped core PEG fragment bound to two dyad-related Fab molecules. A nearby satellite binding site may accommodate parts of a longer PEG molecule. The core PEG fragment mainly interacts with the heavy-chain residues D31, W33, L102, Y103 and Y104, making extensive contacts with the aromatic side chains. At the center of each half-circle of the S-shaped PEG, a water molecule makes alternating hydrogen bonds to the ether oxygen atoms, in a similar configuration to that of a crown ether-bound lysine. Each satellite fragment is clamped between two arginine residues, R52 from the heavy chain and R29 from the light chain, and also interacts with several aromatic side chains. In contrast, the non-specifically bound PEG fragments in the 32D6-Fab crystal are located in the elbow region or at lattice contacts. The AUC data suggest that 3.3-Fab exists as a monomer in PEG-free solution but forms a dimer in the presence of PEG-550-MME, which is about the size of the S-shaped core PEG fragment.ConclusionsThe differing amino acids in 3.3 and 2B5 are not involved in PEG binding but engaged in dimer formation. In particular, the light-chain residue K53 of 2B5-Fab makes significant contacts with the other Fab in a dimer, whereas the corresponding N53 of 3.3-Fab does not. This difference in the protein-protein interaction between two Fab molecules in a dimer may explain the temperature dependence of 2B5 in PEG binding, as well as its inhibition by crown ether.

Tuning Polymer-Protein Interaction with Salt

Biological nanopores are known to interact with synthetic and biological polymers, enabling their use in label-free single-molecule analytical tasks such as sequencing and/or mass discrimination. The latter, called nanopore-based single molecule mass spectrometry (Np-SMMS) has, to date, only been shown for one synthetic polymer, poly(ethyleneglycol) (PEG). It is based on the fact that binding of PEG inside the pore gives rise to blocks of ionic current, with the degree of block being detectably different for PEG molecules differing in size by only one monomer1,2.In order to extend the range of application of Np-SMMS, and to obtain information on the mechanism underying mass sensitivity of polymer-induced pore block, we have begun to test the interaction of other neutral polymers with biological nanoores. Here, we report on poly(dimethylacrylamide) (PDMA), a water-soluble neutral polymer. Under conditions used for Np-SMMS of PEG with alpha-hemolysine (4M KCl, +40 mV), we obtained current blocks with polydisperse PDMA (Mn 1500 g/mol by MALDI) that were low in frequency (<0.1 Hz/ µM) short (tau <100 µs) and noisy, resulting in little mass resolution compared to PEG. We reasoned that we might take advantage of a specific salt effect of fluoride anion reported for the aHL pore3 in order to increase blocking frequency and dwell time. Using electrolyte solutions consiting of 4M K+ as cation and various proportions of Cl- and F- as anions (1:1, 2:1, 3:1, 4:1) we were able to obtain longer events (tau up to 400 µs) and higher frequencies (up to 0.15 Hz/µM), allowing significantly better mass resolution for PDMA than in 4 M KCl. However, the large noise component in the blocked current levels for PDMA as opposed to PEG remained, still compromising the peak-to-valley ratio of histograms. These findings suggest that the specific salt effect of F- on polymer-protein interaction is independent of the polymer and may be useful in tuning polymer pore interaction for a range of analytes.(1) Robertson et al. Single-Molecule Mass Spectrometry in Solution Using a Solitary Nanopore. Proc. Natl. Acad. Sci. U S A 2007, 104, 8207-8211.(2) Baaken et al. High-Resolution Size-Discrimination of Single Nonionic Synthetic Polymers with a Highly Charged Biological Nanopore. ACS Nano 2015, 9, 6443-6449.(3) Rodrigues et al. Hofmeister Effect in Confined Spaces: Halogen Ions and Single Molecule Detection. Biophys. J. 2011, 100, 2929-2935.

Synthesis of poly(ethylene glycol) (PEG) grafted silica nanoparticles with a minimum adhesion of proteins via one-pot one-step method

Abstract The main issue associated with silica nanoparticles (NPs) in biological applications is the adhesion of proteins and blood platelets to the NPs surface. In this work, poly(ethylene glycol) (PEG) grafted silica NPs with low protein adsorption characteristics were synthesized using one-pot one-step Stober's method. The particles were synthesized by the hydrolysis of tetraethylorthosilicate (TEOS) in ethanol under controlled reaction conditions and ammonia as the reaction catalyst. The particle synthesis begins with formation of a silica NP and then PEG grafting is carried out in the presence of TEOS resulting in a silica core–PEG shell nanoparticles. The chemical binding of PEG to the silica NPs was confirmed by Fourier transform infrared spectroscopy (FTIR). The obtained results show that by increasing the PEG/TEOS ratio and decreasing the NH 4 OH concentration, NPs size decreases. The smallest size of PEG grafted NPs ( 4 OH concentration were fixed at 9/1 and 0.5 mol L −1 , respectively. Remarkable reduction in the affinity between modified silica NPs and protein absorption revealed that our proposed method to fabricate hydrophilized PEG grafted NPs, could be potentially utilized in various bioprocess applications.

High-resolution structures of mutants of residues that affect access to the ligand-binding cavity of human lipocalin-type prostaglandin D synthase.

Lipocalin-type prostaglandin D synthase (L-PGDS) catalyzes the isomerization of the 9,11-endoperoxide group of PGH2 (prostaglandin H2) to produce PGD2 (prostaglandin D2) with 9-hydroxy and 11-keto groups. The product of the reaction, PGD2, is the precursor of several metabolites involved in many regulatory events. L-PGDS, the first member of the important lipocalin family to be recognized as an enzyme, is also able to bind and transport small hydrophobic molecules and was formerly known as β-trace protein, the second most abundant protein in human cerebrospinal fluid. Previous structural work on the mouse and human proteins has focused on the identification of the amino acids responsible and the proposal of a mechanism for catalysis. In this paper, the X-ray structures of the apo and holo forms (bound to PEG) of the C65A mutant of human L-PGDS at 1.40 Å resolution and of the double mutant C65A/K59A at 1.60 Å resolution are reported. The apo forms of the double mutants C65A/W54F and C65A/W112F and the triple mutant C65A/W54F/W112F have also been studied. Mutation of the lysine residue does not seem to affect the binding of PEG to the ligand-binding cavity, and mutation of a single or both tryptophans appears to have the same effect on the position of these two aromatic residues at the entrance to the cavity. A solvent molecule has also been identified in an invariant position in the cavity of virtually all of the molecules present in the nine asymmetric units of the crystals that have been examined. Taken together, these observations indicate that the residues that have been mutated indeed appear to play a role in the entrance-exit process of the substrate and/or other ligands into/out of the binding cavity of the lipocalin.

Impact of Membrane Fluidity on Steric Stabilization by Lipopolymers

In this work, the impact of lipid lateral mobility on the steric interaction between membranes containing poly(ethylene glycol) (PEG) functionalized lipids was investigated using the surface force apparatus. The force-distance profiles show the presence of electrostatic and steric repulsion that arise from the presence of negatively charged PEG functionalized lipids. Fluid-phase bilayers have high lateral diffusion relative to gel-phase bilayers; however, a quantitative comparison of the interaction forces between membranes in these two different phase states demonstrates a reduced rate of diffusion in the fluid phase for the PEG-lipids under constrained geometries. Thus, the amount of polymer in the contact zone can be modulated and is reduced with fluid membranes; however, complete exclusion was not achieved. As a result, the steric repulsion afforded by PEG chains or binding affinity of ligated PEG chains can only be modestly tailored by the phase state of the liposome.

Effect of PEG and mPEG-Anthracene on tRNA Aggregation and Particle Formation

Poly(ethylene glycol) (PEG) and its derivatives are synthetic polymers with major applications in gene and drug delivery systems. Synthetic polymers are also used to transport miRNA and siRNA in vitro. We studied the interaction of tRNA with several PEGs of different compositions, such as PEG 3350, PEG 6000, and mPEG-anthracene under physiological conditions. FTIR, UV-visible, CD, and fluorescence spectroscopic methods as well as atomic force microscopy (AFM) were used to analyze the PEG binding mode, the binding constant, and the effects of polymer complexation on tRNA stability, aggregation, and particle formation. Structural analysis showed that PEG-tRNA interaction occurs via RNA bases and the backbone phosphate group with both hydrophilic and hydrophobic contacts. The overall binding constants of K(PEG3350-tRNA)= 1.9 (±0.5) × 10(4) M(-1), K(PEG6000-tRNA) = 8.9 (±1) × 10(4) M(-1), and K(mPEG-anthracene)= 1.2 (±0.40) × 10(3) M(-1) show stronger polymer-RNA complexation by PEG 6000 and by PEG 3350 than the mPEG-anthracene. AFM imaging showed that PEG complexes contain on average one tRNA with PEG 3350, five tRNA with PEG 6000, and ten tRNA molecules with mPEG-anthracene. tRNA aggregation and particle formation occurred at high polymer concentrations, whereas it remains in A-family structure.

Preparation of highly dispersible and tumor-accumulative, iron oxide nanoparticles: Multi-point anchoring of PEG- b-poly(4-vinylbenzylphosphonate) improves performance significantly

This paper describes the preparation of iron oxide nanoparticles, surface of which was coated with extremely high immobilization stability and relatively higher density of poly(ethylene glycol) (PEG), which are referred to as PEG protected iron oxide nanoparticles (PEG-PIONs). The PEG-PIONs were obtained through alkali coprecipitation of iron salts in the presence of the PEG-poly(4-vinylbenzylphosphonate) block copolymer (PEG- b-PVBP). In this system, PEG- b-PVBP served as a surface coating that was bound to the iron oxide surface via multipoint anchoring of the phosphonate groups in the PVBP segment of PEG- b-PVBP. The binding of PEG- b-PVBP onto the iron oxide nanoparticle surface and the subsequent formation of a PEG brush layer were proved by FT-IR, zeta potential, and thermogravimetric measurements. The surface PEG-chain density of the PEG-PIONs varied depending on the [PEG- b-PVBP]/[iron salts] feed-weight ratio in the coprecipitation reaction. PEG-PIONs prepared at an optimal feed-weight ratio in this study showed a high surface PEG-chain surface density (≈0.8 chains nm −2) and small hydrodynamic diameter (<50 nm). Furthermore, these PEG-PIONs could be dispersed in phosphate-buffered saline (PBS) that contains 10% serum without any change in their hydrodynamic diameters over a period of one week, indicating that PEG-PIONs would provide high dispersion stability under in vivo physiological conditions as well as excellent anti-biofouling properties. In fact we have confirmed the prolong blood circulation time and facilitate tumor accumulation (more than 15% ID g −1 tumor) of PEG-PIONs without the aid of any target ligand in mouse tumor models. The majority of the PEG-PIONs accumulated in the tumor by 96 h after administration, whereas those in normal tissues were smoothly eliminated by 96 h, proving the enhancement of tumor selectivity in the PEG-PION localization. The results obtained here strongly suggest that originally synthesized PEG- b-PVBP, having multipoint anchoring character by the phosphonate groups, is rational design for improvement in nanoparticle as in vivo application. Two major points, viz., extremely stable anchoring character and dense PEG chains tethered on the nanoparticle surface, worked simultaneously to become PEG-PIONs as an ideal biomedical devices intact for prolonged periods in harsh biological environments.

Modification of hydrophobic acrylic intraocular lens with poly(ethylene glycol) by atmospheric pressure glow discharge: A facile approach

To improve the anterior surface biocompatibility of hydrophobic acrylic intraocular lens (IOL) in a convenient and continuous way, poly(ethylene glycol)s (PEGs) were immobilized by atmospheric pressure glow discharge (APGD) treatment using argon as the discharge gas. The hydrophilicity and chemical changes on the IOL surface were characterized by static water contact angle and X-ray photoelectron spectroscopy to confirm the covalent binding of PEG. The morphology of the IOL surface was observed under field emission scanning electron microscopy and atomic force microscopy. The surface biocompatibility was evaluated by adhesion experiments with platelets, macrophages, and lens epithelial cells (LECs) in vitro. The results revealed that the anterior surface of the PEG-grafted IOL displayed significantly and permanently improved hydrophilicity. Cell repellency was observed, especially in the PEG-modified IOL group, which resisted the attachment of platelets, macrophages and LECs. Moreover, the spread and growth of cells were suppressed, which may be attributed to the steric stabilization force and chain mobility effect of the modified PEG. All of these results indicated that hydrophobic acrylic IOLs can be hydrophilic modified by PEG through APGD treatment in a convenient and continuous manner which will provide advantages for further industrial applications.

PNA-PEG Modified Silicon Platforms as Functional Bio-Interfaces for Applications in DNA Microarrays and Biosensors

The synthesis and characterization of two types of silicon-based biofunctional interfaces are reported; each interface bonds a dense layer of poly(ethylene glycol) (PEG(n)) and peptide nucleic acid (PNA) probes. Phosphonate self-assembled monolayers were derivatized with PNA using a maleimido-terminated PEG(45). Similarly, siloxane monolayers were functionalized with PNA using a maleimido-terminated PEG(45) spacer and were subsequently modified with a shorter methoxy-terminated PEG(12) ("back-filling"). The long PEG(45) spacer was used to distance the PNA probe from the surface and to minimize undesirable nonspecific adsorption of DNA analyte. The short PEG(12) "back-filler" was used to provide additional passivation of the surface against nonspecific DNA adsorption. X-ray photoelectron spectroscopic (XPS) analysis near the C 1s and N 1s ionization edges was done to characterize chemical groups formed in the near-surface region, which confirmed binding of PEG and PNA to the phosphonate and silane films. XPS also indicated that additional PEG chains were tethered to the surface during the back-filling process. Fluorescence hybridization experiments were carried out with complementary and noncDNA strands; both phosphonate and siloxane biofunctional surfaces were effective for hybridization of cDNA strands and significantly reduced nonspecific adsorption of the analyte. Spatial patterns were prepared by polydimethylsiloxane (PDMS) micromolding on the PNA-functionalized surfaces; selective hybridization of fluorescently labeled DNA was shown at the PNA functionalized regions, and physisorption at the probe-less PEG-functionalized regions was dramatically reduced. These results show that PNA-PEG derivatized phosphonate monolayers hold promise for the smooth integration of device surface chemistry with semiconductor technology for the fabrication of DNA biosensors. In addition, our results confirm that PNA-PEG derivatized self-assembled carboxyalkylsiloxane films are promising substrates for DNA microarray applications.

Preparation of micropatterned hydrogel substrate via surface graft polymerization combined with photolithography for biosensor application

This paper presents a simple method to create protein micropattern on the poly(ethylene glycol) (PEG) hydrogels through the surface graft polymerization and photolithography. The modification of the protein-repellent PEG hydrogel surface was achieved by a two-step process using immobilization of benzophenone on the PEG hydrogel as surface initiator and subsequent surface-initiated polymerization of acrylic acid by UV irradiation. Surface modification of PEG hydrogels was demonstrated with FTIR/ATR spectroscopy and XPS by confirming the presence of carboxyl groups in the poly(acrylic acid) (PAA). The photograft polymerization through the designed photomask produced well-defined, pH-responsive PAA micropatterns with diameters ranging from 50 to 300 μm on the PEG hydrogels. The size of PAA micropatterns was controlled by changing the environmental pH, such that a 300 μm diameter and 17 μm thick PAA micropattern at pH 4 swelled to 480 μm diameter and 80 μm thick at pH 7. Activation of the carboxyl groups in PAA allowed covalent immobilization of proteins only on the PAA micropatterns due to the nonadhesivity of PEG. Based on these results, biotin was micropatterned on the PEG hydrogels and binding of streptavidin was qualitatively and quantitatively investigated, demonstrating the possibility of micropatterned PEG hydrogels for various biosensor systems.

Preparation of magnetite nanocrystals with surface reactive moieties by one-pot reaction

By one-pot reaction, biocompatible magnetite nanocrystals with surface reactive moieties were prepared through the thermal decomposition of Fe(acac) 3 in 2-pyrrolidone using α , ω -dicarboxyl-terminated poly(ethylene glycol) as surface capping molecule. The successful conjugation between the magnetite nanocrystals and 9-amino acridine on the one hand demonstrates the existence of free carboxylic groups from PEG binding on the particle surface, on the other hand may also lead to a new type of magneto-optical materials as well as magneto-drugs.

Crystal structure of TM1367 from Thermotoga maritima at 1.90 Å resolution reveals an atypical member of the cyclophilin (peptidylprolyl isomerase) fold

Crystal structure of TM1367 from <i>Thermotoga maritima</i> at 1.90 Å resolution reveals an atypical member of the cyclophilin (peptidylprolyl isomerase) fold

Poly(ethylene glycol)-Conjugated Human Serum Albumin Including Iron Porphyrins: Surface Modification Improves the O2-Transporting Ability

Artificial O2-carrying hemoprotein composed of human serum albumin including tetrakis(o-amidophenyl)porphinatoiron(II) (Fe4P or Fe3P) [HSA-FeXP] has been modified by maleimide- or succinimide-terminated poly(ethylene glycol) (PEG), and the formed PEG bioconjugates have been physicochemically characterized. 2-Iminothiolane (IMT) reacted with the amino groups of Lys to create active thiol groups, which bind to alpha-maleimide-omega-methoxy PEG [Mw: 2-kDa (PEG(M2)), 5-kDa (PEG(M5))]. On the other hand, alpha-succinimidyl-omega-methoxy PEG [Mw: 2-kDa (PEG(S2)), 5-kDa (PEG(S5))] directly binds to Lys residues. MALDI-TOF MS of the PEG-conjugated HSA-FeXP showed distinct molecular ion peaks, which provide an accurate number of the PEG chains. In the case of PEG(MY)(HSA-FeXP), the spectroscopic assay of the thiol groups also provided the mean of the binding numbers of the polymers, and the degree of the modification was controlled by the ratio of [IMT]/[HSA]. The viscosity and colloid osmotic pressures of the 2-kDa PEG conjugates (phosphate-buffered saline solution, [HSA] = 5 g dL(-1)) were almost the same as that of the nonmodified one, whereas the 5-kDa PEG binding increased the rheological parameters. The presence of flexible polymers on the HSA surface retarded the association reaction of O2 to FeXP and stabilized the oxygenated complex. Furthermore, PEG(MY)(HSA-FeXP) exhibited a long circulation lifetime of FeXP in rats (13-16 h). On the basis of these results, it can be concluded that the surface modification of HSA-FeXP by PEG has improved its comprehensive O2-transporting ability. In particular the PEG(MY)(HSA-FeXP) solution could be a promising material for entirely synthetic O2-carrying plasma expander as a red cell substitute.

Calibration and validation of the 14C-labelled polyethylene glycol-binding assay for tannins in tropical browse

This study evaluates the radiolabelled polyethylene glycol (PEG)-binding procedure [Silanikove, N., Shinder, D., Gilboa, N., Eyal, M., Nitsan, Z., 1996. Polyethylene glycol-binding to plant samples as an assay for the biological effects of tannins: predicting the negative effects of tannins in Mediterranean browse on rumen degradation. J. Agric. Food Chem. 44, 3230–3234] for tannin analysis, using 27 tropical browse plants. In this method, the amount of PEG bound to a plant sample is assumed to be a reflection of its tannin content. The method was modified to exclude the use of non-tanniniferous substrate for estimating non-specific binding (NSB) in tannin-containing substrates. Non-specific binding values varied widely (0.4–2.8 mg PEG/100 mg DM tannin-free substrate) when the tannin-free substrate was changed from wheat straw to either rye grass or maize shoots. We therefore propose a modified radiolabelled PEG-binding method to estimate the level of PEG-binding (PEGb) to tannin-containing foliage without using tannin-free substrate to correct for non-specific binding. In this approach, incremental levels of each tanniniferous substrate were used to generate PEGb values. The resultant linear response was analysed and tannin activity was expressed as the slope of the response curve (PEGbSlope) observed for each substrate. The slope takes into account the non-specific binding in each substrate, thus PEGbSlope does not require correction for NSB using tannin-free samples. This approach improved the correlation between PEGb and the 125I-labelled bovine serum albumin precipitation assay. Relationships between the modified PEG-binding assay and radiolabelled bovine serum albumin assay, in vitro tannin bioassay and colorimetric assays are presented.