Lab-on-valve: universal microflow analyzer based on sequential and bead injection

Růžička, Jaromír

doi:10.1039/b001125h

Cited by 312 publications

(195 citation statements)

References 13 publications

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“…Micro Sequential Injection Lab-On-Valve (µSI-LOV) manifolds alleviate the majority of the drawbacks of FIA methods [12][13][14][15]. This technique is thus an attractive approach for shipboard analysis of trace metals since LOV manifolds are compact, fully automated, and provide highly precise fluidic manipulations in a miniaturized flow manifold with minimal reagent consumption and waste production.…”

Section: Graphical Abstractmentioning

confidence: 99%

Determination of trace zinc in seawater by coupling solid phase extraction and fluorescence detection in the Lab-On-Valve format

Grand

Chocholouš

Ruzicka

et al. 2016

Analytica Chimica Acta

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By virtue of their compactness, long-term stability, minimal reagent consumption and robustness, miniaturized sequential injection instruments are well suited for automation of assays onboard research ships. However, in order to reach the sensitivity and limit of detection required for open-ocean determinations of trace elements, it is necessary to preconcentrate the analyte prior its derivatization and subsequent detection by fluorescence. In this work, a novel method for the determination of dissolved zinc (Zn) at subnanomolar levels in seawater is described. The proposed method combines, for

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Section: Graphical Abstractmentioning

confidence: 99%

Determination of trace zinc in seawater by coupling solid phase extraction and fluorescence detection in the Lab-On-Valve format

Grand

Chocholouš

Ruzicka

et al. 2016

Analytica Chimica Acta

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“…In fact, the LOV unit is devised to incorporate detection facilities, that is, optical devices (namely, diode-array spectrophotometers, charged-coupled devices (CCDs), laser-induced spectrofluorimeters or luminometers) where the communication to the detector and/or the light source are made via optical fibres (see Fig. 3), and where the position of the fibres can be used to adjust the optical light path of the cell [8]. The microfabricated channel system is also amenable to admit conventional sized peripheral devices, thus facilitating the hyphenation with a plethora of modern detection techniques/analytical instruments, such as electrothermal atomic absorption spectrometry [ 23 37 ], depending on the particular chemical assay.…”

Section: Peculiarities Of the Lab-on-valve Microfluidic Systemmentioning

confidence: 99%

“…Following sample loading and clean-up protocols, appropriate eluents can be aspirated, and the eluate propelled to either the flow-through cell or an external detection device, as sandwiched by air or immiscible liquid segments in order to preserve its integrity. The multipurpose flow cell can even be configured to admit bead particles, thereby serving as a platform for real-time monitoring of chemical events at solid surfaces [8], the exploration of cellular activities via immobilized living cells [ 38 , 39 ] as well as the investigation of biomolecular association and dissociation processes [26], as exploited in enzyme-linked immunosorbent assays [ 40 ] and affinity chromatographic methods [ 41 ]. Since the entire protocol sequence is computer controlled, all fluidic unit operations are readily to be re-programmed according to the involved chemistry.…”

Section: Peculiarities Of the Lab-on-valve Microfluidic Systemmentioning

confidence: 99%

“…The LOV microfluidic unit, however, offers a universal means for sample introduction as a result of its singular hardware configuration [8]. The central processing unit in the LOV monolithic structure has been designed to house a flow-through port (see port 5 in Figures 2 and 3), where one channel serves as the sample solution inlet while the other channel works as the sample outlet, which is plugged to an ancillary peristaltic pump.…”

Section: 11-sample Injectionmentioning

confidence: 99%

“…And in 2000 it was extended by the third generation named the Lab-on-a-Valve (LOV) [ 8 ], which was initially spawned as a fluidic universal system for downscaling reagent-based assays to the micro-and submicroliter level. Yet it has concurrently proven to offer vast potentials for accommodation of a wide variety of sample processing steps in a micro-scale according to the requirements of the assays.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Miniaturization of environmental chemical assays in flowing systems: The lab-on-a-valve approach vis-à-vis lab-on-a-chip microfluidic devices

Miró

Hansen

2007

Analytica Chimica Acta

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Flow Injection Analysis Techniques in Atomic Spectroscopy

Pereiro¹,

Sanz‐Medel²

2011

Encyclopedia of Analytical Chemistry

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Flow injection analysis (FIA), developed originally for the automation of serial assays, has become a powerful tool most adequate for performing on‐line any sample preparation before final measurement (e.g. sample dissolution, dilutions, matrix removal, preconcentration, etc.). It is not surprising that the combination of FIA with atomic spectrometric techniques has enlarged the analytical potential of atomic methods and expanded their field of applications. The collection of sample manipulation processes that can be covered today by flow operation procedures is amazing and therefore the general instrumentation required is reviewed in this article. The description of the different flow strategies is carried out according to a hierarchy going from simple dilutions, reagent mixing, or standard additions, to more sophisticated flow manifolds such as those based on the use of two phases (e.g. gas–liquid, liquid–liquid, or solid–liquid) for separation/preconcentration purposes. Modern approaches allowing for on‐line decomposition/dissolution of solid samples (e.g. photooxidation and microwave heating) are also described. The coupling of the above flow methodologies to a variety of atomization/excitation/ionization sources (flames, quartz tubes, graphite furnaces, inductively coupled plasmas (ICPs), microwave‐induced plasmas (MIPs), glow discharges (GDs), etc.) is detailed, aiming to show the usefulness of this combination for atomic techniques based either on photon measurements (absorption, emission, and fluorescence) or on ion measurements (mass spectrometry (MS)).

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Lab-on-valve: universal microflow analyzer based on sequential and bead injection

Cited by 312 publications

References 13 publications

Determination of trace zinc in seawater by coupling solid phase extraction and fluorescence detection in the Lab-On-Valve format

Determination of trace zinc in seawater by coupling solid phase extraction and fluorescence detection in the Lab-On-Valve format

Miniaturization of environmental chemical assays in flowing systems: The lab-on-a-valve approach vis-à-vis lab-on-a-chip microfluidic devices

Flow Injection Analysis Techniques in Atomic Spectroscopy

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