Both stable intermediates of anhydride and NHS-ester were observed after EDC/NHS activation of PMAA, where NHS-ester waxes, while anhydride wanes complementarily with increasing fragmentation degree of PMAA blocks in PMAA-associated polymer blends.
The overwinding and underwinding of DNA duplexes between junctions have been used in designing left-and righthanded DNA origami nanostructures, respectively. For DNA tubes obtained from self-assembled tiles, only a theoretical approach of the intrinsic curvature of the tiles has been previously used to explain their formation. Details regarding the quantitative and structural descriptions of the tile's intrinsic curvature in DNA nanostructures have so far never been addressed. In this work, we designed three types of tile cores built around a circular scaffold using three-and four-branched junctions. Joining the tile cores with arms having two kinds of inter-tile distances, an odd and an even number of DNA half-turns, tended to form planar 2D lattices and tubes, respectively. Streptavidin bound to biotin was used as a labeling technique to characterize the inside and outside surfaces of the tubes and thereby the tile conformation of dihedrals with addressable faces. DNA tubes with either right-or left-handed chirality were obtained by the coupling of the intrinsic curvature of the tiles with the arm twist. We were able to assign the chiral indices (n,m) to a tube with its structure resolved by AFM at the single-tile level and therefore to estimate the global curvature of the tube (or its component tile) using a regular polygon model that approximated its transverse section. A deeper understanding of the integrated actions of different types of twisting forces on DNA tubes will be extremely helpful in engineering more elaborate DNA nanostructures in the future.
Sulfonylurea herbicides are widely used at lower dosage for controlling broad-leaf weeds and some grasses in cereals and economic crops. It is important to develop a highly efficient and selective pretreatment method for analyzing sulfonylurea herbicide residues in environments and samples from agricultural products based on magnetic molecularly imprinted polymers (MIPs). The MIPs were prepared by a surface molecular imprinting technique especially using the vinyl-modified Fe3O4@SiO2 nanoparticle as the supporting matrix, bensulfuron-methyl (BSM) as the template molecule, methacrylic acid (MAA) as a functional monomer, trimethylolpropane trimethacrylate (TRIM) as a cross-linker, and azodiisobutyronitrile (AIBN) as an initiator. The MIPs show high affinity, recognition specificity, fast mass transfer rate, and efficient adsorption performance toward BSM with the adsorption capacity reaching up to 37.32 mg g(-1). Furthermore, the MIPs also showed cross-selectivity for herbicides triasulfuron (TS), prosulfuron (PS), and pyrazosulfuron-ethyl (PSE). The MIP solid phase extraction (SPE) column was easier to operate, regenerate, and retrieve compared to those of C18 SPE column. The developed method showed highly selective separation and enrichment of sulfonylurea herbicide residues, which enable its application in the pretreatment of multisulfonylurea herbicide residues.
We demonstrate a simple and highly sensitive optical fiber relative humidity (RH) sensor based on a long-period fiber grating (LPFG) coated with polyethylene glycol (PEG)/polyvinyl alcohol (PVA) composite films. The resonance wavelength of the LPFG is sensitive to environmental humidity due to the change in effective refractive index caused by the strong surface absorption and desorption of the porous PEG/PVA coatings. The sensor is sensitive in a wide range from 50% to 95% RH, with a highest sensitivity of 2.485 nm/%RH in the range 50–75% RH. The proposed RH sensor has the advantages of compact size, good reversibility, and stability, which makes it attractive for high-humidity environments.
Microarrays hold considerable promise in large-scale biology on account of their analytical, massive and parallel nature. In a step toward further enabling such a capability, we describe the application of rolling circle amplification (RCA) for a sensitive and multiplex detection of nucleic acid targets on oligonucleotide-conjugated polymer brushes covalently grown from porous silicon. Both RCA and polymer brushes have been taken to increase the loading quantity of target molecules and thus improve the detection sensitivity without loss of multiplexing. Besides, polymer brushes were employed to protect porous silicon and to provide biologically simulated environments, making the attached biomolecules maintain bioactivity. This approach can reach a detection limit of 0.1 nM target analytes and three orders of magnitude dynamic range of 0.1-100 nM, with a fluorescence scanner. A two-colour DNA microarray was achieved via RCA of two kinds of circular DNA targets on one chip simultaneously. The porous silicon chip-based RCA technique is promising for the multiplex detection of deoxynucleic acids on microarrays.
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