Gastrodin interaction with human fibrinogen: anticoagulant effects and binding studies

In an effort to identify the anticoagulant activity of gastrodin (GAS) and to investigate the possibility of its use as a novel anticoagulant drug, the binding characteristics of GAS to human fibrinogen (Fg) were studied by using a quartz crystal microbalance (QCM) biosensor, anticoagulant animal experiments, and a molecular docking simulation. Real-time kinetic analysis with the QCM biosensor revealed that the in vitro binding of GAS to Fg was strong under physiological ionic conditions as the determined equilibrium dissociation constant (KD) was 1.94 x 10(-6) M. To check whether this strong binding may influence the natural coagulation function of Fg, the in vivo effect of GAS on the coagulation system of rats was examined. The results showed that GAS can significantly prolong the coagulation time (CT) and decrease the Fg content, while it had no effect on the activated kaolin partial thromboplastin time (KPTT) or prothrombin time (PT) in rats. To clarify the mechanism of the specific interaction, a molecular docking simulation was also performed to provide reasonable binding models for the interaction of GAS with Fg at the atomic level. GAS binds strongly to the inherent polymerization sites "a" and "b" (holes) on the Fg molecule with similar binding free energies of about -34 kJ mol(-1). Altogether, these findings confirmed first that GAS possesses anticoagulant activity and that the possible anticoagulation mechanism of GAS mainly involves its interference with the knob-to-hole interactions between fibrin molecules, thereby effectively inhibiting the formation of clots and decreasing the risk of thrombosis. The study has also shown the potential usefulness of QCM biosensor technology for the rapid screening of drug-protein interactions.     

The effect of surface microtopography of poly(dimethylsiloxane) on protein adsorption, platelet and cell adhesion

Chemical homogeneous poly(dimethylsiloxane) (PDMS) surface with dot-like protrusion pattern was used to investigate the individual effect of surface microtopography on protein adsorption and subsequent biological responses. Fibrinogen (Fg) and fibronectin (Fn) were chosen as model proteins due to their effect on platelet and cell adhesion, respectively. Fg labeled with ¹²⁵I and fluorescein isothiocyanate (FITC) was used to study its adsorption on flat and patterned surfaces. Patterned surface has a 46% increase in the adsorption of Fg when compared with flat surface. However, the surface area of the patterned surface was only 8% larger than that of the flat surface. Therefore, the increase in the surface area was not the only factor responsible for the increase in protein adsorption. Clear fluorescent pattern was visualized on patterned surface, indicating that adsorbed Fg regularly distributed and adsorbed most on the flanks and valleys of the protrusions. Such distribution and local enrichment of Fg presumably caused the specific location of platelets adhered from platelet-rich plasma (PRP) and flowing whole blood (FWB) on patterned surface. Furthermore, the different combination of surface topography and pre-adsorbed Fn could influence the adhesion of L929 cells. The flat surface with pre-adsorbed Fn was the optimum substrate while the virgin patterned surface was the poor substrate in terms of L929 cells spread.     

PuCO体系的分子反应动力学研究

基于多体项展式理论方法导出的PuCO分子基态(X^7A")的分析势能函数,用准经典的Monte-Carlo轨线法对Pu(^7Fg)+CO(0,0)和O(^3Pg)+PuC(0,0)的分子反应动力学过程进行了计算。结果表明：Pu(^7Fg)与CO(0,0)碰撞易生成PuCO配合物分子,该反应是无阈能反应,反应截面σ随能量Et的升高而下降,当Et=502.1kJ.mol^-^1时,σ几乎为零。O(^3Pg)与PuC(0,0)碰撞易发生生成Pu+CO的交换反应,该反应无阈能。     

Surface characterization and protein interactions of segmented polyisobutylene-based thermoplastic polyurethanes

The surface properties and biocompatibility of a class of thermoplastic polyurethanes (TPUs) with applications in blood-contacting medical devices have been studied. Thin films of commercial TPUs and novel polyisobutylene (PIB)-poly(tetramethylene oxide) (PTMO) TPUs were characterized by contact angle measurements, X-ray photoelectron spectroscopy, and atomic force microscopy (AFM) imaging. PIB-PTMO TPU surfaces have significantly higher C/N ratios and lower amounts of oxygen than the theoretical bulk composition, which is attributed to surface enrichment of PIB. Greater differences in the C/N ratios were observed with the softer compositions due to their higher relative amounts of PIB. The contact angles were higher on PIB-PTMO TPUs than on commercial polyether TPUs, indicating lower surface energy. AFM imaging showed phase separation and increasing domain sizes with increasing hard segment content. The biocompatibility was investigated by quantifying the adsorption of fouling and passivating proteins, fibrinogen (Fg) and human serum albumin (HSA) respectively, onto thin TPU films spin coated onto the electrode of a quartz crystal microbalance with dissipation monitoring (QCM-D). Competitive adsorption experiments were performed with a mixture of Fg and albumin in physiological ratio followed by binding of GPIIb-IIIa, the platelet receptor ligand that selectively binds to Fg. The QCM-D results indicate similar adsorbed amounts of both Fg and HSA on PIB-PTMO TPUs and commercial TPUs. The strength of the protein interactions with the various TPU surfaces measured with AFM (colloidal probe) was similar among the various TPUs. These results suggest excellent biocompatibility of these novel PIB-PTMO TPUs, similar to that of polyether TPUs.     

Poly(N-vinylpyrrolidone)-modified surfaces repel plasma protein adsorption

The present work aimed to study the interaction between plasma proteins and PVP-modified surfaces under more complex protein conditions.In the competitive adsorption of fibrinogen(Fg) and human serum albumin(HSA),the modified surfaces showed preferential adsorption of HSA.In 100%plasma,the amount of Fg adsorbed onto PVP-modified surfaces was as low as 10 ng/cm~2,suggesting the excellent protein resistance properties of the modified surfaces.In addition, immunoblots of proteins eluted from the modified surfaces after plasma contact confirmed that PVP-modified surfaces can repel most plasma proteins,especially proteins that play important roles in the process of blood coagulation.     

Pu(7Fg)＋CO(X 1Σ＋，0，0)的分子反应动力学

基于PuCO分子基态()的分析势能函数， 用准经典的Monte Carlo轨线法对Pu(7Fg)＋CO(0，0)的分 子反应动力学过程进行了计算.结果表明, Pu(7Fg)与CO(0，0)碰撞易生成PuCO络合物分子，该反应是无阈能反应，反应截面σ随能量Et的升高而下降，当Et=502.1 kJ•mol－1时，σ几乎为零.     

Inhibition of protein adsorption and cell adhesion on PNIPAAm-grafted polyurethane surface: effect of graft molecular weight

In this work, the effect of molecular weight (MW) of surface grafted poly(N-isopropylacrylamide) (PNIPAAm) on protein adsorption and cell adhesion was investigated systematically. PNIPAAm-grafted polyurethane (PU) surfaces of varying graft MW were prepared via conventional radical polymerization. The MW was controlled by adjusting the monomer concentration. Fibrinogen (Fg) and human serum albumin (HSA) were selected as model proteins and their adsorption from phosphate-buffered saline (PBS, pH 7.4) and blood plasma at 37°C was measured using a radiolabeling method and immunoblot analysis respectively. It was found that in both media, as the MW increased, the adsorption of these two proteins decreased gradually reaching a plateau value at MW above 7.9×10(4). Compared to the unmodified PU, the surface grafted with PNIPAAm of MW 14.6×10(4) reduced the adsorption of Fg and HSA in PBS by 91% and 86%, respectively. Moreover, the surfaces with higher MW PNIPAAm showed minimal adhesion of L929 cells presumably due to the absence of cell-adhesive proteins on the surfaces.     

Research of protein adsorption on the different surface topography of the zinc oxide

The effect of the surface topography on the protein adsorption process is of great significance for designing biomaterial surfaces and the biocompatibility for specific biomedical applications. In this work, we have systematically investigated the mono‐protein adsorption kinetics of bovine serum albumin (BSA) and fibrinogen (Fg) adsorbed on the four different surface topographies (nanoparticles (NPs), nanorods (NRs), nanosheets (NSs) and nanobeams (NBs) of Zinc oxide (ZnO), respectively. The competition of multi‐protein adsorbed on them has been studied as well. Results showed that each protein had a singular process of adsorption that fitted well by Spreading Particle Model (SPM). It confirmed that ZnO NRs compared with other samples had more adsorption sites, which could provide more opportunities for the interaction between material and protein molecules. In addition, the Fg compared to the BSA could be more tightly adsorbed to the surface, both of which existed slight conformational changes by Fourier transform infrared (FTIR) and circular dichroism spectra (CD). Taken together, all these consequences well demonstrated that NRs may have wider applications in designing biomaterial surfaces and the biocompatibility for implanted biomaterials. Copyright © 2014 John Wiley & Sons, Ltd.     

Novel 1,3,5-thiadiazine-2-thione derivatives containing a hydrazide moiety: Design,synthesis and bioactive evaluation against phytopathogenic fungi in vitro and in vivo

A series of novel 1,3,5-thiadiazine-2-thione derivatives bearing a hydrazide moiety were designed, synthesized and evaluated for their biological activities against phytopathogenic fungi. The antifungal bioassays indicated that the title compound 5b impressively displayed the obvious selectivity and specificity aganist Rhizoctonia solani (Rs) in vitro and in vivo. The above researches provide a significant reference for the further structural optimization of 1,3,5-thiadiazine-2-thione derivatives bearing a hydrazide moiety as potential fungicides.     

Partially reduced graphite oxide as an electrode material for electrochemical double-layer capacitors

Partially reduced graphite oxide was prepared from graphite oxide by using synthetic graphite as precursor. The reduction of graphite oxide with a layer distance of 0.57?nm resulted in a reduction of the layer distance depending on the degree of reduction. Simultaneously the amount of oxygen functionalities in the graphite oxide was reduced, which was corroborated by elemental analysis and EDX. The electrochemical activation of the partially reduced graphite oxide was investigated for tetraethylammonium tetrafluoroborate in acetonitrile and in propylene carbonate. The activation potential depends significantly on the degree of reduction, that is, on the graphene-layer distance and on the solvent used. The activation potential decreased with increasing layer distance for both positive and negative activation. The resulting capacitance after activation was found to be affected by the layer distance, the oxygen functionalities and the used electrolyte. For a layer distance of 0.43?nm and with acetonitrile as the solvent, a differential capacitance of 220?Fg(-1) was achieved for the discharge of the positive electrode near the open-circuit potential and 195?Fg(-1) in a symmetric full-cell assembly.     

Stimuli‐responsive antifouling polyisobutylene‐based biomaterials via modular surface functionalization

This article demonstrates a new, modular approach to surface functionalization that harnesses chain entanglement. A layer of functionalized polyisobutylene, (PIB)‐ω, where ω = ‐OH, ‐thymine (T), ‐hexaethylene glycol (HEG), poly(ethylene glycol) (‐PEG‐OH), methoxy‐functionalized poly(ethylene glycol) (‐PEG‐OCH₃), and ‐tetraethylene glycol‐α‐lipoate (TEG‐αL) was adhered to PIB‐based thermoplastic elastomer (TPE) surfaces. X‐ray photoelectron spectroscopy (XPS) at angles ranging from 20° to 75° showed decreasing polar group concentration with increasing penetration depth, confirming segregation of polar groups toward the surface. Water contact angle (WCA) of the PIB‐based TPE dropped from 95° to 79°?83° upon coating, and soaking in water for 24 h further decreased the WCA. Dynamic WCA measurements showed 40–30° receding angles, showing that stimulus from an aqueous environment elicits enrichment of polar groups on the surface. Fibrinogen (Fg) adsorption on the various surfaces was quantified using surface plasmon resonance (SPR). Static and dynamic WCA did not vary significantly among TPE + PIB‐ω surfaces, but there were dramatic differences in Fg adsorption: 256 ng/cm² was measured on the native TPE, which dropped to 40 and 22 ng/cm² on PIB‐PEG‐OCH₃ and PIB‐PEG‐OH‐coated surfaces. PIB‐TEG‐αL‐coated surfaces presented the lowest Fg adsorption with 14 ng/cm². © 2017 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2017 , 55 , 1742–1749     

Molecular simulation to characterize the adsorption behavior of a fibrinogen gamma-chain fragment

Implants invoke inflammatory responses from the body even if they are chemically inert and nontoxic. It has been shown that a crucial precedent event in the inflammatory process is the spontaneous adsorption of fibrinogen (Fg) on implant surfaces, which is typically followed by the presence of phagocytic cells. Interactions between the phagocyte integrin Mac-1 and two short sequences within the fibrinogen gamma chain, gamma190-202 and gamma377-395, may partially explain phagocyte accumulation at implant surfaces. These two sequences are believed to form an integrin binding site that is inaccessible when Fg is in its soluble-state structure but then becomes available for Mac-1 binding following adsorption, presumably due to adsorption-induced conformational changes. The objective of this research was to theoretically investigate this possibility by using molecular dynamics simulations of the gamma-chain fragment of Fg over self-assembled monolayer (SAM) surfaces presenting different types of surface chemistry. The GROMACS software package was used to carry out the molecular simulations in an explicit solvation environment over a 5 ns period of time. The adsorption of the gamma-chain of fibrinogen was simulated on five types of SAM surfaces. The simulations showed that this protein fragment exhibits distinctly different adsorption behavior on the different surface chemistries. Although the trajectory files showed that significant conformational changes did not occur in this protein fragment over the time frame of the simulations, it was predicted that the protein does undergo substantial rotational and translational motions over the surface prior to stabilizing in various preferred orientations. This suggests that the kinetics of surface-induced conformational changes in a protein's structure might be much slower than the kinetics of orientational changes, thus enabling the principles of adsorption thermodynamics to be used to guide adsorbing proteins into defined orientations on surfaces before large conformational changes can occur. This finding may be very important for biomaterial surface design as it suggests that surface chemistry can potentially be used to directly control the orientation of adsorbing proteins in a manner that either presents or hides specific bioactive sites contained within a protein's structure, thereby providing a mechanism to control cellular responses to the adsorbed protein layer.     

Interactive effects of pore size control and carbonization temperatures on supercapacitive behaviors of porous carbon/carbon nanotube composites

Porous carbon-based electrodes were prepared by carbonization with poly(vinylidene fluoride) (PVDF)/carbon nanotube (CNT) composites to further increase the specific capacitance for supercapacitors. The specific capacitance, pore size distribution, and surface area of the PVDF/CNT composites were measured, and the effect of the carbonization temperatures was examined. The electrochemical properties were examined by cyclic voltammetry, impedance spectroscopy, and galvanostatic charge-discharge performance using a two-electrode system in TEABF(4) (tetraethylammonium tetrafluoroborate)/acetonitrile as a non-aqueous electrolyte. The highest specific capacitance of ～101 Fg(-1) was obtained for the samples carbonized at 600 °C. The pore size of the samples could be controlled to below 7 nm through the carbonization process. This suggests that micropores make a significant contribution to the specific capacitance due to improved charge transfer between the pores of the electrode materials and the electrolyte.     

Synthesis of Ru(0.58)In(0.42)O(y)⋅nH(2)O nanoparticles dispersed onto poly(sodium-4-styrene sulfonate)-functionalized multi-walled carbon nanotubes and their application for electrochemical capacitors

In this work, poly(sodium-4-styrene sulfonate) (PSS)-functionalized multi-walled carbon nanotubes (FMWCNTs) were first synthesized via a polymer-assisted technique. Then, Ru(0.58)In(0.42)O(y)?nH(2)O nanoparticles (NPs) were mono-dispersed onto the FMWCNTs surfaces under mild hydrothermal condition. Here, PSS with negative charge serves as a bifunctional molecule both for solubilizing and dispersing MWCNTs into aqueous solution and for tethering Ru(3+) and In(3+) to facilitate the good dispersion of Ru(1-)(x)In(x)O(y)?nH(2)O NPs onto their surfaces. The good dispersion of Ru(0.58)In(0.42)O(y)?nH(2)O NPs onto FMWCNTs makes OH(-) ions and electrons easily contact these NPs with abundant electroactive sites, which results in a large specific capacitance (SC) of 319Fg(-1) for the naocomposites. Moreover, a symmetric electrochemical capacitor (EC) is constructed by using the nanocomposites as electrodes and delivers large specific energy density of 18.1Whkg(-1), desirable power property of 1302Wkg(-1), high electrochemical reversibility and good SC retention of 84.7%.     

聚(甲基丙烯酸-2-羟乙酯)改性金表面用于构建生物检测基材

采用电子活化再生原子转移自由基聚合(AGET ATRP)的方法将聚(甲基丙烯酸-2-羟乙酯)(PHEMA)接枝在金表面,对经修饰的金表面的生物惰性做了系统的研究,并利用PHEMA的羟基末端固定生物素(biotin)分子,以biotin对抗生物素蛋白(avidin)的识别为模型,研究了不同厚度的PHEMA对结合avidin的影响,以及该表面作为生物检测基材的可行性.生物惰性研究表明,PHEMA修饰的金表面不但能够有效的排斥纤维蛋白原(Fg)、人血清白蛋白(HSA)和溶菌酶(Lys)的非特异性吸附,还能够抑制3种细胞(L02、L929和EC)的黏附,是一种良好的抗污表面.通过控制聚合时间制备了不同厚度的PHEMA-biotin修饰的表面,同位素125I标记HSA吸附结果表明这几种表面均能够有效排斥非特异性蛋白质吸附,特异性FITC-avidin吸附结果表明,厚度较小时(16 nm)由于荧光淬灭而难以检测到荧光信号,厚度在16 nm和49 nm之间,荧光信号随厚度增加而增强,通过比较信噪比,认为厚度在49 nm以上时比较理想.该表面在应用于QCM与荧光检测中均表现出良好的检测性能.     

New protein-resistant coatings for water filtration membranes based on quaternary ammonium and phosphonium polymers

Several simple, lightly cross-linked quaternary phosphonium- and ammonium-based polymer coatings were found to effectively resist the non-specific adsorption of proteins (i.e., bovine serum albumin (BSA) and fibrinogen (Fg)) from aqueous solution under both static exposure and dynamic membrane fouling conditions. In some cases, their protein-resistance performance is comparable to, or even better than, cross-linked poly(ethylene glycol) (i.e., PEG)-based polymers, which are considered benchmark protein-resistant coating materials. Similarly, these quaternary phosphonium and ammonium polymers exhibit comparable or better resistance to protein adsorption compared to polymeric analogues of some of the best organic functional groups identified in prior self-assembled monolayer-based protein-resistance studies. In particular, initial results of dynamic membrane fouling experiments showed that lightly cross-linked poly[trimethyl-(4-vinyl-benzyl)-phosphonium bromide] has exceptional protein-fouling resistance and better water transport properties than a representative PEG-based polymer coating. In addition to surface functional group chemistry, it was also found that the sub-surface chemistry; the nature of the substrate that the coating is on (i.e., substrate type and morphology); and the protein exposure conditions (i.e., static adsorption vs. dynamic filtration testing) can greatly affect the overall protein adsorption-resistance behavior of the coating. Finally, preliminary studies show that the presence of a regular nanostructure on the polymeric coating surface can lead to enhancement of protein resistance under static exposure conditions even with the same functional groups present, similar to what has been observed with inorganic surfaces.     

Surface tailoring for controlled protein adsorption: effect of topography at the nanometer scale and chemistry

Protein adsorption behavior is at the heart of many of today's research fields including biotechnology and materials science. With understanding of protein-surface interactions, control over the conformation and orientation of immobilized species may ultimately allow tailor-made surfaces to be generated. In this contribution protein-surface interactions have been examined with particular focus on surface curvature with and without surface chemistry effects. Silica spheres with diameters in the range 15-165 nm with both hydrophilic and hydrophobic surface chemistries have been used as model substrates. Two proteins differing in size and shape, bovine serum albumin (BSA) and bovine fibrinogen (Fg), have been used in model studies of protein binding with detailed secondary structure analysis being performed using infrared spectroscopy (IR) on surface-bound proteins. Although trends in binding affinity and saturation values were similar for both proteins, albumin is increasingly less ordered on larger substrates, while fibrinogen, in contrast, loses secondary structure to a greater extent when adsorbing onto particles with high surface curvature. These effects are compounded by surface chemistry, with both proteins becoming more denatured on hydrophobic surfaces. Both surface chemistry and topography play key roles in determining the structure of the bound proteins. A model of the binding characteristics of these two proteins onto surfaces having differing curvature and chemistry is presented. We propose that properties of an adsorbed protein layer may be guided through careful consideration of surface structure, allowing the fabrication of materials/surface coatings with tailored bioactivity.     

PuN基态分子势能函数与热力学函数的理论计算

在Pu的相对论有效原子实势近似和N原子6-311G*全电子基函数下,用密度泛函B3LYP方法计算得到PuN分子基态X6∑+的结构与势能函数、力常数与光谱数据.同时计算得到PuN(g)分子在298 K时的标准生成热力学函数△fH0、△S0和△fG0,分别为-487.239 kJ/mol、95.345 J/mol K和-515.6661 kJ/mol.     

Interactions of ADP-stimulated human platelets with PEGylated polystyrene substrates prepared by surface amidation

A study primarily focused on the interactions between ADP-stimulated human platelets and PEGylated polystyrene substrates is described in this paper. The platelet–surface interactions were investigated using colorimetric acid phosphatase assay. Two types of amine-containing polymeric hydrogel materials based on poly(ethylene glycol) (PEG), H₂N–PEG–OCH₃ and H₂N–PEG–NH₂, were used to PEGylate polystyrene surfaces derivatized with maleic anhydride by amidation at alkaline pH. In addition, comparative studies using surfaces non-covalently adsorbed by bovine serum albumin (BSA) or fibrinogen (Fg) were also conducted. The assay results showed that no significant platelet adhesion was observed when PEGylated surfaces or BSA-coated surfaces were exposed to unstimulated gel-filtered platelets (GFP). However, upon ADP-stimulation, platelet adhesion to the surfaces under investigation in this study all increased to varying degrees. Most importantly, the results showed that polystyrene surfaces PEGylated using H₂N–PEG–NH₂ were most effective in resisting platelet adhesion when assays were performed using ADP-stimulated GFP. By PEGylating the surfaces of polystyrene microtiter wells via the amidation reaction described in this paper, it is demonstrated that (i) higher degree of surface PEGylation is favored at more alkaline pH and (ii) polystyrene substrates capable of more effectively resisting the adhesion of ADP-stimulated GFP can be obtained by the PEGylation reaction carried out at pH 9.1 using H₂N–PEG–NH₂.     

Design,Synthesis, and Antifungal Activity of 3‐(Thiophen‐2‐yl)‐1,5‐dihydro‐2H‐pyrrol‐2‐one Derivatives Bearing a Carbonic Ester Group

A series of 3‐(thiophen‐2‐yl)‐1,5‐dihydro‐2H‐pyrrol‐2‐one derivatives bearing a carbonic ester group were designed and synthesized by integrating a thiophene nucleus and a pyrroline‐2‐one scaffold in a single molecular architecture. Their structures were confirmed by IR, ¹H‐NMR, EI‐MS, and elemental analyses, and their antifungal activities against Fusarium graminearum (Fg), Rhizoctorzia solani (Rs), and Botrytis cinerea (Bc) were evaluated. The antifungal bioassays indicated that some title compounds exhibited desirable antifungal effects against the tested fungi. Strikingly, the title compounds 4i , 4k , 4n , and 4o showed obvious antifungal activities against Rs, with corresponding EC₅₀ values of 35.26, 33.56, 23.90, and 30.48 μg/mL, respectively, which are better than that of hymexazol (37.86 μg/mL). These results indicated that 3‐(thiophen‐2‐yl)‐1,5‐dihydro‐2H‐pyrrol‐2‐one derivatives bearing a carbonic ester group can serve as potential structural templates in the search for novel high‐efficient fungicides.