ライフサイエンスコーパス: photomultiplier

1 corded over a short period of time using one photomultiplier.

2 odules based on a commercial digital silicon photomultiplier.

3 ultaneously to a sample cell and a reference photomultiplier.

4 a new time-of-flight system based on silicon photomultipliers.

5 Light is collected by 12 x 12 silicon photomultipliers.

6 opment of new PET detectors, such as silicon photomultipliers.

7 24 x 1.4 x 9.5 mm(3)) and 210 low-cost 19-mm photomultipliers.

8 s a 10 x 10 x 1 cm NaI(Tl) crystal with four photomultipliers.

9 tion algorithms and other multimodal silicon photomultiplier and non-silicon photomultiplier PET dete

10 The detectors, photomultipliers and preamps are housed within a 12 cm x

11 ped green laser, an optical train, a channel photomultiplier, and an inertial mass measurement unit a

12 uch as electron-beam accelerator facilities, photomultipliers, and image intensifiers for night visio

13 Amplified photoelectron pulses from the photomultiplier are grouped into bins of 360-450 micros

14 x 3.2 x 20 mm crystals coupled to a silicon photomultiplier array of 16 x 16 mm, resulting in an axi

15 xyorthosilicate crystals read out by silicon photomultiplier arrays.

16 Biophotons were detected using a photomultiplier as a single photon counter.

17 red with both a semiconductor photodiode and photomultiplier as light sensing elements.

18 The recently introduced silicon-photomultiplier-based (SiPM-based) PET/CT (computed tomo

19 c cytometer (PMC) uses a high-speed scanning photomultiplier-based detector to combine low-pixel-coun

20 Biograph Vision 600, using the same silicon photomultiplier-based detectors with 3.2 x 3.2 x 20 mm l

21 e new digital PET/CT system features silicon photomultiplier-based detectors with 3.2-mm lutetium oxy

22 sed effective sensitivity of digital silicon photomultiplier-based PET/CT systems might increase quan

23 ucleic acid detection with the novel silicon photomultiplier-based reader created an innovative produ

24 The platform comprises a novel silicon photomultiplier-based reader in conjunction with a chemi

25 were read out using a novel, compact silicon photomultiplier-based reader.

26 feature offers the back-illuminated silicon photomultiplier broader application opportunities exempl

27 d compared to a commercial fluorometer using photomultiplier detection for detecting active Stx2 in t

28 Photomultiplier detection is employed, and a lock-in amp

29 velength incident light was measured using a photomultiplier detector and correlated to the organopho

30 panning 5 orders of magnitude, comparable to photomultiplier detectors.

31 d by acousto-optic modulators and electronic photomultiplier gating.

32 rystal scintillators and 393 channel silicon photomultipliers has been developed for positronium (Ps)

33 Silicon photomultipliers have attracted increasing attention for

34 of toxicants, using a single photodetector (photomultiplier) is presented.

35 detectors, image sensor arrays, and silicon photomultipliers over a broad spectral range.The perform

36 odal silicon photomultiplier and non-silicon photomultiplier PET detector system designs indicated th

37 o-1 and 9-to-1 to arrays of 3 x 3 mm silicon photomultiplier pixels.

38 integrated with a CT camera, is based on the photomultiplier-quadrant-sharing concept and comprises 1

39 logy have enabled the development of silicon photomultiplier sensor arrays capable of sensing individ

40 I equipped with a pixelated stilbene-silicon photomultiplier (SiPM) array module and low sampling-rat

41 d within a handheld casing housing a silicon photomultiplier (SiPM) detection circuit and a microproc

42 MiniPET-3-that uses state-of-the-art silicon photomultiplier (SiPM) photosensors, making possible dua

43 n of biochemiluminescence relying on silicon photomultiplier (SiPM) technology, called LuminoSiPM, wh

44 Silicon photomultipliers (SiPM) are inexpensive, low-footprint d

45 te-of-the-art photodetectors such as silicon photomultipliers (SiPM).

46 r elements with light collection via silicon photomultipliers (SiPM).

47 ted microfluidics chips coupled with silicon photomultipliers (SiPMs) for high sensitive real-time AT

48 todetectors can rival the commercial silicon photomultipliers (SiPMs) for photon counting.

49 e imaging system presented here uses silicon photomultipliers (SiPMs) in place of PMTs because SiPMs

50 n counting readout properties of the silicon photomultiplier (SPM) with a thermoelectric cooler and t

51 ce novel detection electronics using silicon photomultipliers that greatly extend dynamic range, enab

52 cted end-on by an optical fiber coupled to a photomultiplier, thus, creating an image of the separati

53 Measurement of UPE was carried out by photomultiplier tube (PMT) in the following steps: at th

54 ites, the ECL of luminol is followed using a photomultiplier tube (PMT) or digital camera and the ima

55 2) at the anodic poles was monitored using a photomultiplier tube (PMT) or digital camera.

56 2O2 at the anodic poles is monitored using a photomultiplier tube (PMT) or smartphone, and the images

57 Saturation is directly related to the photomultiplier tube (PMT) voltage settings and RNA abun

58 ed by measuring fluorescence over a range of photomultiplier tube (PMT) voltages by determining the P

59 This allows the use of a single photomultiplier tube (PMT), often the most expensive com

60 Compared with the conventional photomultiplier tube (PMT), the results revealed that th

61 ch) directly coupled to a position-sensitive photomultiplier tube (PS-PMT).

62 al to be recorded in one pass using a single photomultiplier tube and eliminates the need for a polar

63 The ring-down signals are monitored using a photomultiplier tube and recorded using a digital oscill

64 has a high sensitivity because of the use of photomultiplier tube but also can get multiple-point dat

65 on crystals that are coupled to a 64-channel photomultiplier tube by optical fibers.

66 A single photomultiplier tube detects all the modulated emitted l

67 c control, (b) an integrated (and motorized) photomultiplier tube for chemiluminescent detection, and

68 The mass detection limits using a photomultiplier tube for sucrose and glucose are 50 ng,

69 optimization, field of view, resolution and photomultiplier tube performance.

70 parent screen directly on top of a miniature photomultiplier tube provides the basis of an attractive

71 chondrial oxidation was detectable either by photomultiplier tube recordings of flavoprotein fluoresc

72 ions avoiding the need for correction of the photomultiplier tube signal for the gating sequence.

73 n flow through a resin bed interfaced with a photomultiplier tube through a polycarbonate window.

74 s a common disk electrode, spectrometer, and photomultiplier tube to measure the O(ECL).

75 .75 mm each) coupled to a position-sensitive photomultiplier tube via an optical fiber bundle made of

76 complementary metal-oxide semiconductor, or photomultiplier tube).

77 ctors such as single-photon avalanche diode, photomultiplier tube, or arrays of such detectors.

78 t chemiluminescent signal is quantified by a photomultiplier tube, recorded by a miniature onboard co

79 ne in a small reflective cell located atop a photomultiplier tube, resulting in intense CL.

80 nging waveforms from an impedance mismatched photomultiplier tube.

81 d by a highly sensitive, large-dynamic-range photomultiplier tube.

82 e from tumor cells could be detected using a photomultiplier tube.

83 hollow fibers is detected using a miniature photomultiplier tube.

84 ly continuous light guide to an array of 420 photomultiplier tubes (39-mm diameter) in a hexagonal ar

85 Similarly, photomultiplier tubes (PMTs) can generate approximately

86 h significant portions of volume occupied by photomultiplier tubes (PMTs).

87 h the same crystal geometry but conventional photomultiplier tubes (PMTs).

88 ses magnetically shielded position-sensitive photomultiplier tubes and a compact 1-T permanent-magnet

89 th 0.5-mm pixels was coupled to multichannel photomultiplier tubes and evaluated for use as high-reso

90 Because classic PET detectors based on photomultiplier tubes cannot be used in high magnetic fi

91 g 488 and 635 nm lasers with two independent photomultiplier tubes for detection of the FITC and Cy5

92 sparent plastic flow cell placed between two photomultiplier tubes for radiometric detection.

93 e (GSO) crystals to 288 (36 x 8 array) 39-mm photomultiplier tubes in a hexagonal arrangement.

94 e crystal arrays are coupled to multichannel photomultiplier tubes via a tapered, pixelated glass lig

95 n light is transmitted to position-sensitive photomultiplier tubes via optical light guides.

96 ons in aqueous media that can be detected by photomultiplier tubes with good sensitivity, without the

97 iodide crystal, a 2 x 2 array of 53 x 53 mm photomultiplier tubes, and a parallel-hole collimator (1

98 Conventional two-photon microscopes use photomultiplier tubes, which enable high sensitivity but

99 tection rate as compared to state-of-the-art photomultiplier tubes.

100 ar polarizations and collected onto separate photomultiplier tubes.

101 the flat-panel multianode position-sensitive photomultiplier tubes.

102 Adjusting photomultiplier voltage while measuring fluorescence int

103 intillator directly coupled to a multi-anode photomultiplier was developed as an alternative for SESA

104 PET/CT devices, including the replacement of photomultipliers with avalanche photodiodes and the need

105 ecently introduced PET systems using silicon photomultipliers with digital readout (dPET) have an imp

106 nto next-generation back-illuminated silicon photomultiplier would increase the photon detection effi