Organic
thin-film transistors (OTFTs) have attracted intense attention as
promising electronic devices owing to their various applications such
as rollable active-matrix displays, flexible nonvolatile memories,
and radiofrequency identification (RFID) tags. To further broaden
the scope of the application of OTFTs, we focus on the host–guest
chemistry combined with the electronic devices. Extended-gate types
of OTFTs functionalized with artificial receptors were fabricated
to achieve chemical sensing of targets in complete aqueous media.
Organic and inorganic ions (cations and anions), neutral molecules,
and proteins, which are regarded as target analytes in the field of
host–guest chemistry, were electrically detected by artificial
receptors. Molecular recognition phenomena on the extended-gate electrode
were evaluated by several analytical methods such as photoemission
yield spectroscopy in the air, contact angle goniometry, and X-ray
photoelectron spectroscopy. Interestingly, the electrical responses
of the OTFTs were highly sensitive to the chemical structures of the
guests. Thus, the OTFTs will facilitate the selective sensing of target
analytes and the understanding of chemical conversions in biological
and environmental systems. Furthermore, such cross-reactive responses
observed in our studies will provide some important insights into
next-generation sensing systems such as OTFT arrays. We strongly believe
that our approach will enable the development of new intriguing sensor
platforms in the field of host–guest chemistry, analytical
chemistry, and organic electronics.
First selective nitrate biosensor device based on an extended-gate type organic field-effect transistor (OFET) is reported. The fabricated sensor device consists of the extended-gate electrode functionalized by a nitrate reductase with a mediator (=a bipyridinium derivative) and an OFET-based transducer. The mechanism of the nitrate detection can be explained by an electron-relay on the extended-gate electrode, resulting in changes of the electric properties of the OFET. The detection limit of nitrate in water is estimated to be 45 ppb, which suggests that the sensitivity of our fabricated sensor is comparable to those of some conventional detection methods. As a practical application of the OFET sensor, the nitrate detection in diluted human saliva has been successfully demonstrated; the results agreed well with those by conventional colorimetric measurement. The advantages of OFETs are printability, mechanical flexibility, stretchability and disposability, meaning that the fabricated OFET could open up a new approach for low-cost electronic devices toward on-site detection of nitrate in aqueous media.
Activation-induced cytidine deaminase (AID) introduces DNA cleavage in the Ig gene locus to initiate somatic hypermutation (SHM) and class switch recombination (CSR) in B cells. The DNA deamination model assumes that AID deaminates cytidine (C) on DNA and generates uridine (U), resulting in DNA cleavage after removal of U by uracil DNA glycosylase (UNG). Although UNG deficiency reduces CSR efficiency to one tenth, we reported that catalytically inactive mutants of UNG were fully proficient in CSR and that several mutants at noncatalytic sites lost CSR activity, indicating that enzymatic activity of UNG is not required for CSR. In this report we show that CSR activity by many UNG mutants critically depends on its N-terminal domain, irrespective of their enzymatic activities. Dissociation of the catalytic and CSR activity was also found in another UNG family member, SMUG1, and its mutants. We also show that Ugi, a specific peptide inhibitor of UNG, inhibits CSR without reducing DNA cleavage of the S (switch) region, confirming dispensability of UNG in DNA cleavage in CSR. It is therefore likely that UNG is involved in a repair step after DNA cleavage in CSR. Furthermore, requirement of the N terminus but not enzymatic activity of UNG mutants for CSR indicates that the UNG protein structure is critical. The present findings support our earlier proposal that CSR depends on a noncanonical function of the UNG protein (e.g., as a scaffold for repair enzymes) that might be required for the recombination reaction after DNA cleavage.N-terminal region deletion ͉ point mutants ͉ SMUG1 I n response to antigen stimulation, the Ig locus of B cells undergoes 2 types of DNA modification: class switch recombination (CSR) and somatic hypermutation (SHM) (1). CSR and SHM diversify antibodies in 2 different modes: SHM introduces point mutations in the recombined V(D)J region, whereas CSR changes the heavy-chain constant (C H ) region by looping-out deletion of upstream C H genes, which is mediated by DNA cleavage and relegation of 2 different switch (S) regions located 5Ј to each C H gene. CSR results in switching Ig isotype from IgM to IgG, IgA, or IgE, keeping the same antigen specificity but altering effector functions of the expressed antibody.AID has been shown to be essential to both CSR and SHM (2, 3), which are initiated by introducing DNA breaks in V and/or S regions (4-6). However, the molecular mechanism of DNA cleavage by AID has been a subject of controversy. The RNA editing model postulates that AID edits an unknown mRNA to generate endonuclease or its cofactor (7). On the other hand, the DNA deamination model (8-10) proposes that AID deaminates cytidine (C) to uridine (U) in S regions, generating U/G mismatches, which are recognized by the base excision or mismatch repair pathway. The majority of Us are proposed to be processed by uracil DNA glycosylase (UNG) and an apurinic/apyrimidic endonuclease, generating single-stranded nicks and staggered double-strand breaks (DSBs) in CSR.According to the DNA deamination model...
Herein, we report an organic field effect transistor (OFET) with an extended-gate modified by an artificial receptor for the detection of mercury(II) ions (Hg(2+)) in water. The sensor device is easy to fabricate, reusable, disposable, and portable. Thus OFET sensors could be applied for low-cost on-site detection of Hg(2+).
Simple, rapid, and accurate detection methods for saccharides are potentially applicable to various fields such as clinical and food chemistry. However, the practical applications of on-site analytical methods are still limited. To this end, herein, we propose a 96-well microtiter plate made of paper as a paper-based chemosensor array device (PCSAD) for the simultaneous classification of 12 saccharides and the quantification of fructose and glucose among 12 saccharides. The mechanism of the saccharide detection relied on an indicator displacement assay (IDA) on the PCSAD using four types of catechol dyes, 3nitrophenylboronic acid, and the saccharides. The design of the PCSAD and the experimental conditions for the IDA were optimized using a central composite design. The chemosensors exhibited clear color changes upon the addition of saccharides on the paper because of the competitive boronate esterification. The color changes were employed for the subsequent qualitative, semiquantitative, and quantitative analyses using an automated algorithm combined with pattern recognition for digital images. A qualitative linear discrimination analysis offered discrimination of 12 saccharides with a 100% classification rate. The semiquantitative analysis of fructose in the presence of glucose was carried out from the viewpoint of food analysis utilizing a support vector machine, resulting in clear discrimination of the various concentrations of fructose. Most importantly, the quantitative detection of fructose in two types of commercial soft drinks was also successfully carried out without sample pretreatments. Thus, the proposed PCSAD can be a powerful method for on-site food analyses that can meet the increasing demand from consumers for sensors of saccharides.
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