Fibre loop cavity ring-down spectroscopy for the sensitive and selective detection of minute sample volumes of liquid explosives

Rushworth, Catherine; Vallance, Claire

doi:10.1117/12.868950

Cited by 4 publications

(1 citation statement)

References 18 publications

(21 reference statements)

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“…Most of the previous cavity-based measurements have been made on gas-phase analytes as low background scattering and absorption by gases allows a very high number of passes (>10 4 with suitable high reflectivity mirrors) to be achieved. Only a few liquid-phase, cavity-based studies have been reported to date as the solvent-related scattering and absorption losses are much higher. − However, for bioanalytical applications the majority of analytes are in the liquid-phase. Many of the previous liquid-phase studies have used CRDS and have focused on using CRDS as a detection method for high performance liquid chromatography (HPLC).…”

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confidence: 99%

Cavity-Enhanced Immunoassay Measurements in Microtiter Plates Using BBCEAS

et al. 2016

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We report on the first detailed use of broadband cavity enhanced absorption spectroscopy (BBCEAS) as a detection system for immunoassay. A vertical R ≥ 0.99 optical cavity was integrated with a motorized XY stage, which functioned as a receptacle for 96-well microtiter plates. The custom-built cavity enhanced microplate reader was used to make measurements on a commercially available osteocalcin sandwich ELISA kit. A 30-fold increase in path length was obtained with a minimum detectable change in the absorption coefficient, αmin(t), of 5.3 × 10–5 cm–1 Hz–1/2. This corresponded to a 39-fold increase in the sensitivity of measurement when directly compared to measurements in a conventional microplate reader. Separate measurements of a standard STREP-HRP colorimetric reaction in microtiter plates of differing optical quality produced an increase in sensitivity of up to 115-fold compared to a conventional microplate reader. The sensitivity of the developed setup compared favorably with previous liquid-phase cavity enhanced studies and approaches the sensitivity of typical fluorometric ELISAs. It could benefit any biochemical test which uses single pass absorption as a detection method, through either the label free detection of biologically important molecules at lower concentrations or the reduction in the amount of expensive biochemicals needed for a particular test, leading to cheaper tests.

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