A highly sensitive aptasensor for on‐site detection of lipopolysaccharides in food

A rapid, low‐cost, highly sensitive, and specific capacitive aptasensor is presented for detection of lipopolysaccharides (LPS). Exposure to LPS could cause fever, gram‐negative sepsis, septic shock, and eventual death. Hence, rapid, low cost, and sensitive detection of LPS is pivotal for the safety of food, pharmaceutical, and medical devices and products. In this work, a capacitive sensing method based on alternating current electrokinetics is developed to achieve rapid and specific detection of LPS. This method uses an alternating current signal for two purposes. One is to induce positive dielectrophoresis, which attracts LPS toward the sensor electrodes’ surface and accelerates its binding with the immobilized aptamer probe. The other purpose is to simultaneously sense the binding reaction by measuring the interfacial capacitance change on the electrodes’ surface. The testing procedures and instrumentation setup of this sensing platform are significantly simplified while finding quantitative concentrations of both analytical and complex samples within 30 s. When testing analytical samples of LPS from Escherichia coli O55:B5, a LOD of 4.93 fg/mL is achieved. The recovery analysis is also performed with LPS spiked in a complex matrix and good recovery rates are demonstrated. This work provides an affordable and field‐deployable platform for highly sensitive and real‐time LPS detection.     

Recent development in chitosan nanocomposites for surface‐based biosensor applications

Recent years have witnessed ever expanding use of biosensors in the fields of environmental monitoring, homeland security, pharmaceutical, food and bioprocessing, and agricultural industries. To produce effective and reliable biosensors, good quality immobilization of biological recognition elements is critical. Chitosan and its nanocomposites emerge as an excellent immobilization matrix on biosensor surface. As a natural polysaccharide, chitosan has many useful characteristics, such as high permeability and mechanical strength, biocompatibility and non‐toxicity, availability, and low cost. Due to the presence of amino and hydroxyl groups on chitosan, chitosan can easily crosslink with a variety of nanomaterials. This investigation of chitosan nanocomposite‐based biosensors presents recent development and innovations in the preparation of chitosan nanocomposites in coordination with biosensors for various bio‐detection applications, including chitosan nanocomposites formed with carbon nanomaterials, various inorganic and biological complexes. These chitosan nanocomposite based biosensors have demonstrated good sensitivity selectivity and stability for the detection of different types of targets ranging from glucose, proteins, DNAs, small biomolecules to bacteria. It is in our hope that this review will offer guidance for the development of novel biosensors and open up opportunities in the field of biosensor research.     

Electrophilic cleavage of cyclopropylmethystannanes: an experimental comparison of sigma-sigma and sigma-pi conjugation

[reaction: see text] Cyclopropylmethyltrimethylstannanes undergo electrophilic cyclopropane cleavage in chloroform with simple inorganic electrophiles (H(+), SO(2), I(2)) in a homologous reaction to the S(E)' cleavage of allylic stannanes. The sigma-sigma conjugation between the carbon-tin bond and cyclopropane orbitals observed spectroscopically in the parent cyclopropylmethyltrimethylstannane is responsible for a rate enhancement of ca. 10(2) toward iodinolysis, relative to comparable alkyl stannanes. This acceleration is considerably less, however, than the ca. 10(9)-fold rate enhancement provided by the corresponding sigma-pi conjugation in allylic stannanes. Methanol-tin coordination appears to reduce the activating influence of the metal, promoting methyl cleavage over cyclopropane fission with acid and iodine. Decreased sigma-sigma conjugation can also explain the decreased reactivity of cyclopropyltriphenylstannane compared with its trimethyltin counterpart. Cyclopropylmethylstannanes do not undergo the synthetically useful addition of aldehydes under conditions that facilitate the corresponding reaction of allylic stannanes.     

Local protection for surgical implants

In this issue of Chemistry & Biology, Jose and coworkers [1] describe the covalent attachment of vancomycin to a titanium surface. The tethered antibiotic is effective against S. aureus, suggesting that this material has the potential to complement clinical strategies for preventing infection following implant surgery.     

Bridging the Gap Between First and Second Semester General Chemistry: A Laboratory Exercise

A simple yet challenging exercise that reviews many fundamental chemical concepts and laboratory techniques from first semester general chemistry is offered for use in the first laboratory period of the second semester general chemistry course. This exercise is easy to do and involves a minimal amount of equipment and reagents. Students at the authors school like this exercise because they get good results, yet feel challenged because they have to think for themselves.     

Semiconducting polymer thin films by surface-confined stepwise click polymerization

Surface-confined stepwise click polymerization was used to prepare surface-attached thin films of semiconducting polymers. These highly uniform films showed extended UV/vis absorption characteristics and a remarkable degree of molecular organization with a unidirectional alignment of the polymer chains normal to the surface.     

Reactions of Dimethyl Heteroaroylphosphonates with Trialkyl Phosphite in the Presence of Proton Donors

Abstract

We have previously shown that substituted bcnzoylphosphonates (1; Ar ? X-Ph) react with trimethyl phosphite to give anionic intermediates which in the absence of electrophiles decompose to give carbene intermediates (3). The nature of the subsequent reaction products depends on the type and position of the substituents on the aromatic ring.ll1 When proton donors are present the initially formed anionic intermediates (2) give the quasi-phosphonium salts (4) which usually decompose to give the phohphonate-phosphates (5). although for the case of (1; Ar ? 4-MeOPh) formation of the phosphonates (6) was observed.