Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Rapid screening

Guo Z and C L Brooks III 1998. Rapid Screening of Binding Affinities Application of the A-Dynamics Method to a Trypsin-Inhibitor System. Journal of the American Chemical Society 120 1920-1921. [Pg.651]

Thin-layer chromatography (tic) (16) is frequently used. The procedure allows for rapid screening for most dmgs of abuse using simple, inexpensive technology. A drawback to tic, however, is that the technique is not especially sensitive and low levels of dmgs may be missed. [Pg.486]

Immunosensors promise to become principal players ia chemical, diagnostic, and environmental analyses by the latter 1990s. Given the practical limits of immunosensors (low ppb or ng/mL to mid-pptr or pg/mL) and their portabiUty, the primary appHcation is expected to be as rapid screening devices ia noncentralized clinical laboratories, ia iatensive care faciUties, and as bedside monitors, ia physicians offices, and ia environmental and iadustrial settings (49—52). Industrial appHcations for immunosensors will also include use as the basis for automated on-line or flow-injection analysis systems to analyze and control pharmaceutical, food, and chemical processing lines (53). Immunosensors are not expected to replace laboratory-based immunoassays, but to open up new appHcations for immunoassay-based technology. [Pg.30]

The first application is related to tire molecular interaction between surface-liirked DNA and pollutants or dmgs, in order to develop a simple device for rapid screening of toxic compounds or better to try to quantify the genotoxicity of a specific sample. [Pg.15]

An on-line chromatography/atmospheric pressure chemical ionization tandem mass spectrometry (LC-APCI/MS/MS) methods was developed for rapid screen of pharmacokinetics of different drugs, including 5 (98RCM1216). The electron impact mass spectrum of 5 and ethyl 9,10-difluoro-3-methyl-7-oxo-2,3-dihydro-7Ff-pyrido[l,2,3- fe]-l,4-benzoxazine-6-carboxylate was reported (97MI28). Electron impact/Fourier transform... [Pg.268]

Column coupling proves to be a rapid screening approach in identifying chiral selectivity in the most efficient and economical way. In addition to the potential for the simultaneous analysis of a mixture, the coupling practice offers the advantages... [Pg.42]

Although the preparation of the quite complex selector modules prior to the synthesis of the library represented a rather significant synthetic effort, this study showed clearly the potential of combinatorial chemistry in the early development stage of a chiral separation medium and demonstrated a novel approach to rapid screening that might be amenable to full automation in the future. [Pg.70]

It should be pointed out that when using ethidium bromide the sensitivity of the assays varies depending on the physical state of the nucleic acids (see Table I). Ethidium does not discriminate between RNA and DNA, although dyes are available which bind DNA exclusively, so the relative amounts of each may be determined by taking two sets of measurements. Alternatively, nucleases (DNA-ase or RNA-ase) can be used to exclusively remove one or the other in a mixture. Nucleic acids from different sources (see Table II) also show a variation in sensitivity, and the fluorescence assay lacks the selectivity of the hybridization technique. Nevertheless, for rapid screening or quality-control applications the fluorescence assay is still the method of choice. [Pg.48]

Bioassays can be used for cost-effective biomonitoring and rapid screening of environmental samples to detect the presence of mixtures of toxic chemicals and to identify hot spots. [Pg.254]

Even when highly rehable computer modeling techniques exist for dehydrogenases, the need for rapid screening of dehydrogenases will remain, both to verify the predictions experimentally and to determine basic kinetic parameters (substrate... [Pg.296]

Once we have developed our basic model and shown how it may be used to estab-hsh trends in electrochemical reactivity, we will take the further step of applying it to the identification of new bimetallic electrocatalysts. We will introduce simple procedures to rapidly screen bimetallic alloys for promising electrocatalytic properties, and we will demonstrate the importance of including estimates of the alloys stabihty in the screening procedure. Finally, we will give examples of successful apphcation of this method to specific problems in the area of electrocatalyst development. [Pg.58]

Fernandez JL, Walsh DA, Bard AJ. 2005b. Thermodynamic guidelines for the design of bimetallic catalysts for oxygen electroreduction and rapid screening by scanning electrochemical microscopy. M-Co (M Pd, Ag, Au). J Am Chem Soc 127 357-365. [Pg.308]

A multi-residue method for 25 selected pesticides including propanil using an SPE disk has also been developed as a rapid screening method for organic contaminants in river, lake and seawater samples. Cig SPE disks are conditioned with 10 mL of acetone for 3 h. Water samples (1L) are allowed to percolate through the disks in order to trap the residues at a fiow rate of 50 mL min under vacuum. Residues trapped in the disks are extracted twice by eluting with 5 mL of dichloromethane-ethyl acetate (1 1, v/v). The more hydrophobic compounds (log/fow>3) seem to show no... [Pg.340]

High throughput screening is one of the hot topics in heterogeneous catalysis. Advanced experimental techniques have been developed to screen and develop solid catalysts for gas-phase systems. However, for catalytic three-phase systems, rapid screening has got much less attention [1-6]. Three-phase catalysis is applied in numerous industrial processes, from synthesis of fine chemicals to refining of crade oil. [Pg.419]

Ide HM, Moss WD, Gautier MA. 1985. Rapid screening methods for the analysis of Pu or Am in urine. Health Phys 49 970-976. [Pg.243]

Table 8.39 shows the main features of EDXRF. EDXRF is not able to detect the fine structure of the K, L, M, etc. lines. EDXRF is used for applications which require measurement of a limited number of elements, and where the resolution and ultralow detection limits of wavelength-dispersive systems are not necessary. For example, EDXRF has been used as a rapid screening technique for the determination of Br and Sb in plastic recyclate at a LOD of 5 ppm [230] the method was validated by means of NAA [231]. Conventional EDXRF systems and benchtop units have a limited detection capability for low-Z-elements and cannot directly measure fluorine in processing aids. [Pg.630]

It is of particular interest that MALDI-ToFMS, which is not the most obvious choice for the analysis of additives in solution, finds practical application for rapid screening of polymer/additive dissolutions. [Pg.702]

Applications MALDI-ToFMS is at its best as a rapid screening technique for quick identification of known additives. However, this screening is rendered slightly more complicated by the fact that MALDI-ToFMS spectra of pure additives and of additives in the presence of excess macromolecules are not always identical (matrix effect) [55]. For unknown additives, the relation MALDI-ToFMS spectrum-chemical structure is not easily established, and the use of FD or MALDI-MS/MS is then needed. As MALDI-MS shows a sensitivity difference for the various additives, it cannot easily quantify them unless the analytes are very similar. For differentiation of additives with the same mass number (e.g. Tinuvin 315 and Cyasorb UV3638 with m/z = 368) high resolution is required, as provided by delayed extraction MALDI-ToFMS. [Pg.703]

It is concluded that MALDI-ToFMS is a suitable method for direct analysis of low-MW additives in complex polymeric materials (in dissolution), in particular as a rapid screening technique (within 0.5 h). However, in order to turn this method into a general tool for identification and quantitation, considerably more work needs to be done. Identification of additives in polymeric matrices by means of MALDI-ToFMS would greatly benefit from reference libraries of additives contained in such matrices. This is not unlike the situation observed for ToF-SIMS. [Pg.709]


See other pages where Rapid screening is mentioned: [Pg.150]    [Pg.20]    [Pg.603]    [Pg.247]    [Pg.187]    [Pg.248]    [Pg.195]    [Pg.62]    [Pg.13]    [Pg.246]    [Pg.204]    [Pg.322]    [Pg.39]    [Pg.46]    [Pg.296]    [Pg.299]    [Pg.105]    [Pg.101]    [Pg.700]    [Pg.707]    [Pg.92]    [Pg.227]    [Pg.233]    [Pg.311]    [Pg.331]    [Pg.402]    [Pg.408]    [Pg.451]    [Pg.735]    [Pg.735]    [Pg.737]   
See also in sourсe #XX -- [ Pg.164 ]

See also in sourсe #XX -- [ Pg.295 ]




SEARCH



Assays rapid screening

Cassette accelerated rapid rat screen (CARRS

Cassette accelerated rapid rat screening

Cassette accelerated rapid rat screening CARRS)

Cassette-accelerated rapid rat screen

Electrospray rapid screening

Libraries screening rapidly

Polyolefins rapid screening

Rapid Screening of Biocatalysts

Rapid polymer screening calculations

Rapid screening of novel dehydrogenases

Rapid screening schemes

Rapid screening systems

Rapid screening techniques

Rapid sequence screening

Screening methods rapid mapping

Sequential Method for Rapid Screening

© 2024 chempedia.info