ライフサイエンスコーパス: microbeam

1 k to each cell individually by using a laser microbeam.

2 reexisting hair cells were killed by a laser microbeam.

3 ir cells were killed individually by a laser microbeam.

4 as severed near the kinetochore with a laser microbeam.

5 th the power density of the two-photon laser microbeam.

6 nderwent irradiation with arrays of parallel microbeams.

7 several groups are also developing electron microbeams.

8 red as arrays of parallel microplanar beams (microbeams), 25- to 90-microm thick and spaced 100-300 m

9 en conducted a series of studies using laser microbeam ablation of amphidial cell bodies in the L1 to

10 in the living L1 was prepared, so that laser microbeam ablation studies can be conducted.

11 The succession of two microbeam analyses on an individual particle allows the

12 Furthermore, our high-precision microbeam analysis revealed that the survival and potent

13 e, speed of preparation, and suitability for microbeam analysis, all of which are favorable for nucle

14 -dicarboxyy-2,2'-bipyridine) was analyzed by microbeam and contextualized.

15 two-photon excitation, one-photon excitation microbeam and X-rays.

16 ere ablated in hatchling larvae with a laser microbeam, and these were grown to the L3 stage and test

17 X-ray microbeams are an emerging characterization tool with br

18 termined the activation potential of the NIR microbeam as a function of wavelength.

19 The availability of the microbeam at the Radiological Research Accelerator Facil

20 a spatial fractionation of synchrotron X-ray microbeams at the microscale level.

21 Together with muXRD, microbeam Ca K-edge X-ray absorption near-edge structure

22 However, such thin microbeams can only be produced by synchrotron sources a

23 ing component of a machine and consists of a microbeam clamped at both ends by fixed supports with a

24 techniques were applied in external (in-air) microbeam configuration for the trace and main element d

25 Apart from localized heating effects, the microbeam damage is probably associated with the O3 load

26 of the SHG spatial profiles following X-ray microbeam exposure was consistent with an EFISH mechanis

27 helium ions using the Gray Cancer Institute microbeam facility targeting individual cells.

28 Without rapid dose delivery, the microbeam geometry is susceptible to blurring due to phy

29 -speed polarized optical microscopy, in situ microbeam grazing incidence wide-angle X-ray-scattering

30 The development of microbeams has allowed nontargeted responses such as bys

31 tweezers based on tightly focused ultrasound microbeam have attracted considerable attention owing to

32 geting of cells in experimental systems with microbeams have led to a reassessment of the model of ho

33 onomy of the Geiseltal anurans using diverse microbeam imaging and chemical analytical techniques.

34 ing subcellular targeting using a soft X-ray microbeam in combination with GNPs.

35 using a soft X-ray (carbon K-shell, 278 eV) microbeam in MDA-MB-231 breast cancer and AG01522 fibrob

36 sed near-infrared continuous wave (CW) laser microbeam in the path of an advancing axon, we discovere

37 h knowledge of the long-term radiobiology of microbeams in healthy tissues is required.

38 ized to a submicron region following a laser microbeam induction showed a whole cell viscosity change

39 on, were measured across individual control, microbeam-irradiated or bystander IMR90 cells.

40 micropallet release produced by pulsed laser microbeam irradiation at lambda = 532 nm using pulse dur

41 ed by picosecond and nanosecond pulsed laser microbeam irradiation in adherent cell cultures.

42 pallet release accomplished via pulsed laser microbeam irradiation is an energy-driven plasma-mediate

43 recent improvements in throughput now permit microbeam irradiation of large cell numbers, allowing th

44 Microbeam irradiation of sensorimotor cortex did not aff

45 cellular outcome resulting from pulsed laser microbeam irradiation spanning a nearly two-orders-of-ma

46 was used to examine the use of pulsed laser microbeam irradiation to produce cell lysis.

47 The time-resolved images show the laser microbeam irradiation to result in plasma formation at t

48 n be precisely controlled by combining laser microbeam irradiation with different fluorescent fusion

49 s of 0.5 ns to 50 mus after the pulsed laser microbeam irradiation, and fluorescence assays assess th

50 time that simple DSBs, induced by USX or NIR microbeam irradiation, are repaired rapidly involving Ku

51 ata, combined with data from studies of 6 ns microbeam irradiation, demonstrates the primacy of shear

52 red cell studies, we examined alpha-particle microbeam irradiation-induced bystander effects in human

53 l airway epithelial cells, using a precision microbeam irradiator with a beam width of 1 mum.

54 availability of a precision single-particle microbeam, it is possible to demonstrate, unequivocally,

55 scein (6-CF) dye and cut with an argon laser microbeam (lambda = 488 nm).

56 velopmental potential of the PTCs by using a microbeam laser to ablate specific clusters in larvae.

57 ere necessary for DLM development by using a microbeam laser to ablate them singly and in combination

58 uclear volumes of cells by means of a pulsed microbeam laser, gamma-H2AX foci form at these sites.

59 estigate mechanical behaviours of 3D printed microbeams made from living cells and extracellular matr

60 A laser microbeam marked the location of cultured neurons on cov

61 and we develop mechanical models of cell-ECM microbeam mechanics.

62 The microbeam method was further used to analyze the depth d

63 work using native UiO-66 crystals yielded a microbeam method which avoided beam damage, while subseq

64 in diameter) of the guard cell wall using a microbeam of ultraviolet light generated by a nitrogen l

65 ividual cells by focussing a sublethal laser microbeam onto them.

66 tunable titanium-sapphire (700-990 nm) laser microbeam optical traps.

67 In those studies, a laser microbeam or ototoxic antibiotics were used to damage th

68 ments were suspended between the tips of two microbeams oriented perpendicular to the filament axis:

69 Using microbeam particle-induced X-ray emission (uPIXE), we sp

70 Reactive gliosis was evident in the microbeam path of rats irradiated with 150 Gy, whereas n

71 ing mechanisms by which optical tweezers and microbeams perturb metabolic function and cellular viabi

72 2+ and K+, we used a quantitative technique, microbeam proton-induced X-ray emission, to measure Ca2+

73 Using laser microbeam pulse durations of 180-1100 ps and pulse energ

74 Reductions in both the threshold laser microbeam pulse energy for plasma formation and the cavi

75 Pulsed laser microbeam radiation at lambda = 532 nm was delivered to

76 behind the favorable response of tissues to microbeam radiation therapy (MRT) are not fully describe

77 Microbeam radiation therapy (MRT) using high doses of sy

78 Microbeam radiation therapy is a novel preclinical techn

79 Microbeam Radiation Therapy is a preclinical form of spa

80 Microbeam radiotherapy (MRT) is based on a spatial fract

81 nchrotron X-ray broad beam and a multiplanar microbeam radiotherapy beam.

82 e promising preclinical results, translating microbeam SFRT to the clinic has been hindered by a reli

83 the X-ray dose, the XEOL-XANES data from the microbeam showed significant dose-dependent changes to t

84 ions in an ensemble of scanning transmission microbeam small-angle X-ray scattering (muSAXS) patterns

85 sophisticated targeting strategy, involving microbeams smaller than the crystal, and translations of

86 Using the recently available microbeam source at the Radiological Research Accelerato

87 exposed transaxially to four 400-Gy, 0.68-mm microbeams, spaced 4 mm, and all four rats irradiated to

88 Here we show that in situ microbeam surface X-ray scattering can determine whether

89 Microbeam synchrotron X-ray diffraction (XRD) and X-ray

90 asma mass spectrometric (ICPMS) analyses and microbeam synchrotron X-ray fluororescence (mu-SXRF) map

91 ine Blue for laser microdissection with PALM microbeam systems.

92 ise to the germ line are killed with a laser microbeam, the lifespan of the animal is extended.

93 irradiated with helium ions from a particle microbeam, the yield of micronuclei (MN) in the nontarge

94 et microtubule-based structures with a laser microbeam through the use of enhanced yellow fluorescent

95 We therefore used a laser microbeam to create DNA damage at discrete sites in the

96 By using a laser microbeam to cut just the lateral projections of the AP

97 We have used a laser microbeam to damage the postsynaptic fibers at individua

98 We used a laser microbeam to either sever a univalent along the plane of

99 Using a laser microbeam to eliminate one of the two centrosomes in bin

100 excitation with a near-infrared (NIR) laser microbeam to investigate activation of channelrhodopsin

101 this model was directly tested by using a UV microbeam to sever axoneme-nucleated microtubules and th

102 We have used a laser microbeam to sever the connection between the motile cen

103 it is the first report applying a soft X-ray microbeam to study the radiobiological effects of GNPs t

104 In this paper, we used a precision microbeam to target an exact fraction (either 100% or <

105 Gamma-H2AX analysis allowed microbeams to be traced and DNA damage foci to be quanti

106 sed focused, polychromatic synchrotron X-ray microbeams to penetrate multilayer materials and simulta

107 ue that uses polychromatic synchrotron X-ray microbeams to probe local crystal structure, orientation

108 suggest potential application of interlaced microbeams to treat tumors or to ablate nontumorous abno

109 his stress by bending single-crystal silicon microbeams using an in situ thermomechanical testing sta

110 A charged-particle microbeam was used, allowing irradiation of cells in def

111 Using a laser microbeam, we ablated single cells from both o and p bla

112 nction of power of the two-photon excitation microbeam, we determined the activation potential of the

113 ing the Columbia University charged particle microbeam, we found that mitochondrial DNA-depleted huma

114 Using a precision charged particle microbeam, we show here that irradiation of 20% of rando

115 also ablated single blast cells with a laser microbeam, which allowed us to assess potential signals

116 estigated by using a high-LET heavy particle microbeam, which allows selected cells to be individuall

117 ngle alpha particles uses a charged-particle microbeam, which irradiates individual cells or cell nuc

118 emonstrated by the use of the two-photon NIR microbeam, which was not possible using single-photon ac

119 tron emission spectromicroscopy (X-PEEM) and microbeam X-ray diffraction (muXRD).

120 address this, we employed operando scanning microbeam X-ray diffraction, operando X-ray photoelectro

121 dard samples measured with tabletop confocal microbeam X-ray fluorescence setup and by comparing the

122 The confocal microbeam X-ray fluorescence technique is a well-establi

123 from an original combination of synchrotron microbeam X-ray fluorescence, absorption spectroscopy, a

124 of transition metal dichalcogenides by using microbeam X-ray photoelectron spectroscopy and scanning

125 As well as charged particle microbeams, X-ray microprobes have been developed, and s