A Comparative Study of Electrochemical Reduction of 4‐Nitrophenyl Covalently Grafted on Gold and Carbon

4‐Nitrophenyl layers were grafted on gold and glassy carbon surfaces by electrochemical reductive adsorption of the corresponding diazonium salt. Electrochemical conversion efficiencies of 4‐nitrophenyl moieties to 4‐aminophenyl moieties on gold versus on glassy carbon in a protic medium were investigated using X‐ray photoelectron spectroscopy (XPS). In total contrast to all previous comparative studies showing greater electrochemical reactivity of aryl diazonium salt‐derived layers on gold than on glassy carbon, a much lower rate of conversion to 4‐aminophenyl was observed on gold than on glassy carbon by both cyclic voltammetry (CV) and chronoamperometry (CA) methods. The lower electron transfer rate during conversion observed on gold versus glassy carbon was proposed to be due to a mechanism related to the molecular structure rearrangement of 4‐nitrophenyl during the process on glassy carbon. However, whilst complete conversion of 4‐nitrophenyl to 4‐aminophenyl on gold by chronoamperometry was achieved, on glassy carbon complete reduction could not be achieved under the same conditions.     

Development of a Rapid Single‐Drop Analysis Biosensor for Screening of Phenanthrene in Water Samples

Detection techniques for biosensors often require bulky instruments or cells that are not feasible for in‐field analysis. Our single‐drop cell design, optimized in this work, comprised a screen‐printed three‐electrode (SPE), strip in horizontal position onto which a volume of 100 μL of sample or substrate solution was placed to ensure electrical contact (complete circuit). Together with optimized linear sweep voltammetry (LSV), parameters for the detection of the enzyme alkaline phosphatase (AP), the system was applied to a biosensor for the analysis of polycyclic aromatic hydrocarbons (PAHs), in environmental samples. A limit of detection (LOD), of 0.15 ppb was achieved for a model system with an IC₅₀ value of 0.885 ppb and a linear range (LR), of 0.2–10 ppb. Application of the single drop analysis (SDA), format to a PAH biosensor gave a LOD of 1.4 ppb for detection of phenanthrene with an IC₅₀ value of 29.3 ppb and linear range of 2–100 ppb. Proof of concept is shown with spiked sample analysis of phenanthrene in matrices such as sea, river and tap water.     

在线固相萃取富集反相液相色谱法测定水中的铅、镉、汞、银

研究了用色谱柱在线固相萃取富集,二极管矩阵检测器检测,反相液相色谱法测定水中铅、镉、汞和银的方法。水样中的铅、镉、汞和银用四-(对氨基苯基)-卟啉(T4APP)柱前衍生后,样品通过富集柱富集,然后切换六通转换阀改变流向,用流动相反向洗脱让显色产物洗下并通过分析柱分离,用二极管矩阵检测器检测。该方法用于测定水样中低含量的铅、镉、汞和银,结果令人满意。     

Synthesis of PEG derivatives bearing aminophenyl and their application for liquid-phase synthesis of water-soluble unsymmetrical cyanine dyes

The synthesis and NMR characterization of soluble PEG-supported polymers were described, and their subsequent application for liquid-phase synthesis of water-soluble cyanine dyes was also studied. Nucleophilic substitution of tosylation of PEG 16 with 1,3-bis(4-nitrophenoxy)-2-propanol 15 under basic conditions, followed by nitro group reduction, gave PEG-bound aminophenyl 18. Another PEG-bound aminophenyl 28 was prepared by condensation reaction of PEG-bound pentaerythritol 25 and 4-aminobenzoic acid followed by the cleavage of BOC group. Subsequent loading and activation of sulfoindoleninium to PEG derivatives 18 or 28 were achieved via simple strategies. Cyanine dyes were released by the attack of heterocyclic carbon nucleophile and the cleavage of PEG-bound hemicyanine without the chromatographic separation. The efficient, facile, and practical approaches appear to be robust and versatile strategies to deliver not only indocyanine dyes but also benzoindocyanine dyes.     

Detection of glucose in synthetic tear fluid using dually functionalized gold nanoparticles

A simple fluorescent sensing of glucose in aqueous fluids (e.g. tear fluid) using dually functionalized gold nanoparticles is presented. As a first step gold nanoparticles (AuNPs) were synthesized using oxidised dextran which acted both as reducing and stabilizing agent. Aminophenyl boronic acid was conjugated onto AuNPs by Schiff's base formation and the formed Schiff's base was stabilized by sodium borohydride reduction. Rhodamine B isothiocyanate (RBITC) was then assembled onto the modified AuNPs. The fluorescence of RBITC was nearly quenched and found to be revived when glucose was added. It is reasoned that the glucose binding induces restructuring of the surface assembly resulting in an overall increase in the size and thereby enhancing the distance between the gold core and fluorophore. TEM image and size measurements using dynamic light scattering (DLS) in fact, reflected this possibility. The increase in fluorescence was proportional with the concentration of glucose enabling quantitative detection. A good linearity was observed between the fluorescence intensity and glucose concentration in a range of 0.025-0.125 μM with detection limit of 0.005 ± 0.002 μM. The potential of the method was demonstrated by measuring glucose in real tear fluids collected from volunteers. The method is extremely sensitive and can be employed to measure low concentration of glucose in aqueous fluids such as tear.     

Pteridines. Part CXVIII

Our approach to achieve a partial synthesis of methanopterin ( 1 ) started from 6‐acetyl‐O⁴‐isopropyl‐7‐methylpterin ( 20 ) which was obtained either by condensation from 6‐isopropoxypyrimidine‐2,4,5‐triamine ( 19 ) and pentane‐2,3,4‐trione ( 6 ) or from 6‐isopropoxy‐5‐nitrosopyrimidine‐2,4‐diamine ( 21 ) and pentane‐2,4‐dione (=acetylacetone; 22 ) (Scheme 2). NaBH₄ reduction of 20 led to 6‐(1‐hydroxyethyl)‐O⁴‐isopropyl‐7‐methylpterin ( 23 ) which was converted into the corresponding 6‐(1‐chloroethyl) and 6‐(1‐bromoethyl) derivatives 24 and 25 . A series of nucleophilic displacement reactions in the side chain and at position 4 were performed as model reactions to give 26 – 29, 32 – 35 , and 39 – 41 . Hydrolysis of the substituents at C(4) led to the corresponding pterin derivatives 30, 31, 36 – 38 , and 42 . Analogously, 25 reacted with 1‐(4‐aminophenyl)‐1‐deoxy‐2,3: 4,5‐di‐O‐isopropylidene‐D ‐ribitol ( 43 ), prepared from N‐(4‐bromophenyl)benzamide ( 47 ) via 49 and 50 to give 1‐{4‐{{1‐[2‐amino‐7‐methyl‐4‐(1‐methylethoxy)pteridin‐6‐yl]ethyl}amino}phenyl}‐1‐deoxy‐D ‐ribitol ( 44 ) in 62% yield (Scheme 3). Acid cleavage of the isopropylidene groups at room temperature led to 45 and on boiling to 1‐{4‐{[1‐(2‐amino‐3,4‐dihydro‐7‐methyl‐4‐oxopteridin‐6‐yl)ethyl]amino}phenyl}‐1‐deoxy‐D ‐ribitol ( 46 ). The next step, however, attachment of the ribofuranosyl moiety with 55 or 56 to the terminal 1‐deoxy‐D ‐ribitol OH group could not been achieved. The second component, bis(4‐nitrobenzyl) 2‐{[(2‐cyanoethoxy)(diisopropylamino)phosphino]oxy}pentanedioate ( 61 ), to built‐up methanopterin ( 1 ) was synthesized from 2‐hydroxypentanedioic acid ( 59 ) and worked well in another model reaction on phosphitylation with N⁶‐benzoyl‐2′,3′‐O‐isopropylideneadenosine and oxidation to give 62 (Scheme 6).