ライフサイエンスコーパス: autosampler

1 via a syringe-based interface mounted on an autosampler.

2 3 freeze-thaw cycles over 3 days, and on the autosampler.

3 servoir containing the IS solution using the autosampler.

4 g batch sample processing and analysis in an autosampler.

5 ab-sampling and 24-h-composited samples from autosamplers.

6 column-switching system, constructed using 1 autosampler, 2 HPLC pumps, and a 10-port switching valve

7 degree of automation makes the developed EME-autosampler a powerful tool for a wide range of applicat

8 a 37 degrees C with a temperature-controlled autosampler and column oven.

9 hip, serves functionally as a combination of autosampler and nanoelectrospray ionization source.

10 uch as the stability of lycopene in the HPLC autosampler and the effect of saponification upon lycope

11 nd reagents are delivered by the pump or the autosampler and the reactions can be monitored by the UV

12 f two samples via dual injection ports on an autosampler and two completely independent flowpaths lea

13 (employing a micropump), automated (using an autosampler), and capillary HPLC modes of operation are

14 rocedures from residue methods, placed in an autosampler, and injected directly into a triple quadrup

15 omposed of one binary LC pumping system, one autosampler, and one mass spectrometer.

16 calculation is the contribution made by the autosampler as an example of one type of error that is n

17 ans-lycopene in the HPLC mobile phase in the autosampler at 4 degrees C was determined to be approxim

18 de profile such as the residence time in the autosampler at 4 degrees C, stopping or not stopping the

19 Analytes were stable on the autosampler, at room temperature, at 4 degrees C, and wh

20 The autosampler attaches to a standard ABI Procise sequencer

21 rity, processing recovery and matrix effect, autosampler carryover, run size, stability, and data rep

22 dansylated derivative into the CTC-PAL Leap autosampler coupled to a Sciex API 4000 mass spectromete

23 Using four autosamplers coupled to one chromatographic column and o

24 As the autosampler drew sample solution, analytes were extracte

25 use of a commercially available multipurpose autosampler equipped with two microsyringes of different

26 shifts and variance in sample loading due to autosampler error.

27 of electro membrane extraction (EME) into an autosampler for high-throughput analysis of samples by E

28 similar to instruments using a conventional autosampler (for Bruker instruments, a BACS) although th

29 oupled to a gas chromatograph with headspace autosampler (HS-GC-MS/MS) was elaborated in this study.

30 The autosampler in Biacore 3000 permitted whole cells expres

31 Our strategy is based on rapid autosampler-in-needle-derivatization with p-toluenesulfo

32 e used in a fully automated mode by using an autosampler injector.

33 into the injection loop using a conventional autosampler (injector) needle pickup from a sample vial.

34 tormwater events at 5 min intervals using an autosampler installed at the residential catchment outle

35 ry columns were interfaced with a commercial autosampler instrument using a novel procedure which all

36 es was performed automatically using an HPLC autosampler, involves minimal sample handling, thus mini

37 igh-performance liquid chromatography (HPLC) autosampler is used for automated sample preparation, in

38 The autosampler is used in combination with faster Edman cyc

39 ion of bacterial isolates and a computerized autosampler is used to make possible a large number of r

40 In-field performance of GFS equipped autosamplers is demonstrated using ground and streamwate

41 respectively; persistent carryover from the autosampler limited the LOQ achievable.

42 including both the column equilibration and autosampler movement.

43 serve as self-powered pre-concentrators and autosamplers of analytes in ambient groundwater and as i

44 duced into the OPSI using a widely available autosampler platform utilizing low cost disposable pipet

45 A commercial autosampler provides reproducible and unattended sample

46 en 100 and 1000 ng/mL), and determination of autosampler stability (samples were stable for at least

47 Method validation included 24-h autosampler stability and one freeze-thaw cycle stabilit

48 racy and precision values, recovery studies, autosampler stability, and freeze-thaw stability.

49 o a luer lock adapter connected to a HTC PAL autosampler syringe.

50 Employing the autosampler system for spatially resolved liquid extract

51 We have designed and implemented an autosampler that provides additional sample capacity on

52 serially into the capillary reactor from an autosampler, they react in parallel in the capillary rea

53 ple samples to multiple injectors allows the autosampler time to complete its wash cycles and aspirat

54 (GC) analysis by placing the disk into a GC autosampler vial containing 1 mL of N,O-bis(trimethylsil

55 trifuged, the supernate is transferred to an autosampler vial, and 10 microL is injected into the LC-

56 0 pg of protein (330 attomole) loaded in the autosampler vial.

57 emtomole virus particles) were loaded to the autosampler vial.

58 plate setup, was adapted to use 1.5 mL glass autosampler vials instead, which facilitated sampling an

59 A LEAP Technologies autosampler was customized to perform the automated samp

60 RSD, <10%; R(2), 0.994) and finally, the EME-autosampler was used to analyze in vitro conversion of m

61 g box designed and constructed in-house, the autosamplers were synchronized with the mass spectromete

62 technique--the coupling of a headspace (HS) autosampler with a programmed temperature vaporizer (PTV

63 signed to interface directly with commercial autosamplers (with no prior modification), suggesting th