ライフサイエンスコーパス: dead volume

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1 es, carryover from run to run, and increased dead volume.

2 stagnant sample associated with the injector dead volume.

3 ntained a 13 mum spacer to minimize detector dead volume.

4 traditional capillary GC columns without any dead volumes.

5 channel exit ensures subnanoliter postcolumn dead volumes.

6 n or elimination, or both, of detection cell dead volume, (2) the ability to interrogate a nearly pur

7 d to transient analysis by virtue of its low dead volume and high sensitivity.

8 ffect of design variations such as change in dead volume and pillar size within the lateral channels

9 icated devices not only significantly reduce dead volume and sample consumption but also increase the

10 stic microfluidics, significant reduction in dead volume and sample consumption can be achieved using

11 Delivery kinetics depend on the dead volume and the rate of carrier flow.

12 This LC-ESII/MS approach has little dead volume and thus provides excellent chromatographic

13 To minimize the analysis time, dead volumes and capacities of all components were optim

14 This is mainly attributed to dead volumes and chromatographic processes introduced by

15 the goal of increasing sensitivity, reducing dead-volume and peak band broadening, optimizing combust

16 In addition to its compactness, negligible dead volume, and robustness, the device can be used at a

17 the electrosprayed liquid and minimized the dead volume associated with droplet formation at the ele

18 In addition, there is no dead volume associated with the porous design, and becau

19 pening and out of the capillary, there is no dead volume associated with this interface.

20 m microchip to capillary indicated a minimum dead volume at the junction.

21 ion of molybdate, which eluted mainly in the dead volume, but had no negative effect on higher thiola

22 hout the immobilized protein to evaluate the dead volume, but this creates several experimental and t

23 m (LMCS), was interfaced to an optimized low dead volume combustion interface to preserve <300 ms ful

24 With the use of a PicoClear tee, the dead volume connection between a 50 microm i.d.

25 The use of such arrays as ultralow-dead-volume detectors in microscale gas chromatographic

26 e been optimized for use in flow-through low-dead-volume electrochemical cells.

27 irectly connected to the gel column via zero dead volume fused-silica connectors.

28 Moreover, the small dead volume in our system allowed for high dynamic contr

29 A side-on interface was designed to minimize dead volume in the nLC x muFFE interface, eliminating th

30 0 microl of sample consumption, inclusive of dead volume in the reservoirs.

31 nnels of a microchip enabled simple and zero dead volume integration of the preconcentration with SDS

32 f high aspect ratio channels allows for zero dead volume interfaces between the microchip platform an

33 e use of postcolumn switching and associated dead volume issues.

34 f fabrication, universality, and lack of any dead volume make this design a superior CE/ESI-MS interf

35 xing chamber, a capillary column, and a zero dead-volume microelectrospray interface.

36 The low dead volume of the emitter arrays preserved peak shape a

37 eparation (little is added to the postcolumn dead volume of the LC system).

38 Dead volumes of different CVC lumens vary considerably.

39 t outlet pressures up to 0.8 atm using a low-dead-volume polymer-coated surface acoustic wave (SAW) d

40 c separation and detection using a true zero dead-volume sheathless CE-MS interface.

41 sheathless FESI device eliminates postcolumn dead volume since small particles (</= 10 micron) are pa

42 The multiemitter device has a low dead volume to facilitate coupling to capillary liquid c

43 wall intact and, therefore, does not add any dead volume to the CE-MS or nLC-MS interface.

44 The integrated nanoESI emitter adds no dead volume to the LC separation, allowing stable electr

45 A low-dead-volume valve, connected between the column junction

46 tention coefficient is the evaluation of the dead volume, which is the retention volume that would be

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