A novel approach for monitoring extracellular acidification rates: based on bead injection spectrophotometry and the lab-on-valve systemElectronic supplementary information (ESI) available: Derivation of eqn. (4). See http://www.rsc.org/suppdata/an/b3/b315007k/

Erxleben, H.; Manion, Michael K.; Hockenbery, David M.; Scampavia, Louis; Růžička, Jaromír

doi:10.1039/b315007k

Cited by 25 publications

(16 citation statements)

References 28 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The second approach has proven to be a very powerful tool in many contexts and implemented in the various generations of flow injection (14). Not the least for bioanalytical assays encompassing investigation of cellular activities (15,16) and enzymatic procedures for determination of both substrates and enzymatic activities (17,18), where the latter one traditionally has been very difficult to execute.…”

Section: X2 Fundamentals Of Flow Injection Analysismentioning

confidence: 99%

“…Nowadays, a wide array of bead particles (predominantly with a core of Sephadex type copolymers) with various surface characteristics are commercially available, and in the following section will be described procedures for real-time monitoring of cellular activities via immobilized live cells (15,72), isolation and on-column fluorimetric detection of DNA (15), optimization of immobilization protocols for proteins (74), as well as investigation of biomolecular association and dissociation processes as exploited in enzyme-linked immunosorbent assays (75) and affinity chromatographic methods (59,60,76). Yet before that, it might be of interest to compare the LOV with the socalled micro-total analysis systems (μTAS) (77), or as they lately have been termed Lab-on-a-Chips (LOC), which are exploited for bionanotechnological applications (78,79).…”

Section: X6 Microfluidic Devices: Lab-on-valvementioning

confidence: 99%

“…Combining LOV and bead injection (BI), Ruzicka and coworkers have in particular focused on cellular analyses and immunoassays (15,67,(74)(75)(76). The former are being used for screening of potential drugs by in-vitro evaluation of biological responses.…”

Section: X72 Bioseparations and Cellular Assaysmentioning

confidence: 99%

See 2 more Smart Citations

Flow Injection Analysis in Industrial Biotechnology

Hansen

Miró

2009

Encyclopedia of Industrial Biotechnology

View full text Add to dashboard Cite

Flow injection analysis (FIA) is an analytical chemical continuous flow (CF) method which, in contrast to traditional CF procedures, does not rely on complete physical mixing (homogenization) of the sample and the reagent(s) or on attaining chemical equilibria of the chemical reactions involved. Exploiting controllable dispersion of the injected sample within the reagent‐containing carrier stream and strictly reproducible timing of all events taking place, it is based on measuring transient signals, which not only implies very high sampling rates but also, and most importantly, permits implementation of a number of novel methodologies that are not feasible when performed under batch conditions or by conventional CF procedures. Demonstrated for selected bioanalytical and technological applications encompassing cellular and enzymatic assays as well as monitoring of culture media, the principles and operational characteristics of FIA are first outlined, and then its downscaled/miniaturized sequels, that is, sequential injection analysis (SIA) and lab‐on‐valve (LOV), are detailed. Thus, in SIA the sample and reagents are, via the use of a multi‐position valve and an attached syringe pump operated under full programmable control, aspirated sequentially and then propelled forward allowing the sample and reagent(s) to be intermixed and, if called for, subjected to appropriate treatments before analyte detection. This infers that, merely minute sample/reagent volumes are consumed, hence leading to generation of small amounts of waste. In LOV this downscaling is taken further by using a small monolithic structure within which all sample manipulations and ultimate analyte detection under programmable control can be effected. Even bead materials with different surface groups/characteristics, including live cells, can be handled and utilized as demonstrated. Because the syringe pump in SIA and LOV can be used for accurately aspirating, propelling or even stopping the flow, these modi operandi allow fully to exploit the interplay between the kinetics and the thermodynamics of the chemical reactions involved, so that there are no restrictions whatsoever as to the chemistries that can be implemented, even if they entail multistep reactions. Representative bioanalytical examples of this interplay are presented.

show abstract

Section: X2 Fundamentals Of Flow Injection Analysismentioning

confidence: 99%

Section: X6 Microfluidic Devices: Lab-on-valvementioning

confidence: 99%

See 1 more Smart Citation

Flow Injection Analysis in Industrial Biotechnology

Hansen

Miró

2009

Encyclopedia of Industrial Biotechnology

View full text Add to dashboard Cite

show abstract

“…For bioassays, antibodies or antigens [15,[21][22][23][24][25] have been immobilized on magnetic [21,22] or polysaccharide-based [24,25] beads. The latter have also been proven suitable as substrate for cell cultivation [26,27].…”

Section: Analytical Procedures For Bead Injection 51 Bead Modificationmentioning

confidence: 99%

“…For example, consumption of glucose and extrusion of lactate could be detected sensitively and rapidly due to the high concentration of immobilized cells [47]. The exploration of cellular activities based on the release of proton from cells in LOV was also reported [27]. Though bead injections were done manually here, two micro-packed bead columns were uniquely created within one section of the LOV micro-channel, as shown in Figure 4A.…”

Section: Cellular Assays/activitiesmentioning

confidence: 99%

Recent developments in automatic solid-phase extraction with renewable surfaces exploiting flow-based approaches

Miró

Hartwell

Jakmunee

et al. 2008

TrAC Trends in Analytical Chemistry

View full text Add to dashboard Cite

. (2008). Recent developments in automatic solid-phase extraction with renewable surfaces exploiting flow-based approaches. TRAC -Trends in Analytical Chemistry, 27(9), 749-761. DOI: 10.1016749-761. DOI: 10. /j.trac.2008 TrAC MS:08-00052-REVISED Abstract: Solid-phase extraction (SPE) has been consolidated as the most versatile sample processing method for removal of interfering species and/or analyte enrichment. Although significant advances have been conducted over the past two decades for automation of the entire analytical protocol involving SPE via flow injection approaches, on-line SPE assays performed in a permanent mode lack sufficient reliability as a consequence of the progressive tighter packing of the bead reactor, contamination of the solid surfaces and potential leakage of functional moieties. This article overviews the current state-of-the-art of an appealing tool for overcoming the above shortcomings, the so-called bead injection (BI) analysis, based on automated renewal of the sorbent material per assay exploiting the various generations of flow injection analysis. It addresses novel instrumental developments for implementation of BI and a number of alternatives for on-line chemical derivatization reactions and pinpoints the most common instrumental detection techniques utilised. Relevant environmental and bioanalytical applications reported within the past few years are presented and discussed in detail.

show abstract