ライフサイエンスコーパス: multiphoton imaging

1 e combined with technologies such as in vivo multiphoton imaging.

2 e clearance in aged Tg2576 mice with in vivo multiphoton imaging.

3 cruitment by coupling mechanical loading and multiphoton imaging.

4 multiple columns and layers using high-speed multiphoton imaging.

5 grating online image analysis with automated multiphoton imaging.

6 ity with multicolor labeling and confocal or multiphoton imaging.

7 nd brain vessels when measured by intravital multiphoton imaging and immunohistochemistry.

8 in assemblies have been employed for in vivo multiphoton imaging and lifetime-based oxygen measuremen

9 In vivo multiphoton imaging and neural manipulations delineated

10 Here we use multiphoton imaging and patch-clamp recording, and obser

11 We use in vivo multiphoton imaging and show that mechanical forces duri

12 ined molecular dynamics simulations, Laurdan multiphoton imaging, and atomic force microscopy microin

13 the laser power required for adaptive optics multiphoton imaging, and for facilitating integration wi

14 Our results demonstrate that multiphoton imaging can be used for fast and sensitive c

15 Intravital multiphoton imaging, confocal imaging of cryosections an

16 modes demonstrate a significant advantage of multiphoton imaging; data can be obtained from deeper wi

17 Live, multiphoton imaging demonstrated a selective vulnerabili

18 Multiphoton imaging does not suffer from degradation of

19 le cells (abGCs) in the olfactory bulb using multiphoton imaging in awake and anesthetized mice.

20 In this study, we used multiphoton imaging in Foxp3-GFP mice to examine the beh

21 Ca2+ transients, measured with multiphoton imaging in individual fibers within a whole

22 dmium selenide-zinc sulfide quantum dots for multiphoton imaging in live animals.

23 ritic structure of neocortical neurons using multiphoton imaging in live mice in vivo and investigate

24 Multiphoton imaging is a form of fluorescence microscopy

25 A method was developed based on multiphoton imaging of 4',6'-diamino-2-phenylindole (DAP

26 In vivo multiphoton imaging of CD11c-EYFP mice revealed that int

27 Both studies use in vivo multiphoton imaging of cortical axons to show that synap

28 Multiphoton imaging of developing mouse cortex reveals t

29 Multiphoton imaging of freshly prepared brain slices loa

30 Multiphoton imaging of GFP-labeled neurons in living Tg2

31 by Malpighi to the current use of single and multiphoton imaging of intravital and isolated perfused

32 In this study, we used multiphoton imaging of live rat kidney slices to investi

33 Multiphoton imaging of presynaptic NMDAR-mediated calciu

34 inflammatory events (day 3 of UUO), in vivo multiphoton imaging of the intact kidney of CD11c report

35 We conducted in vivo time-lapse multiphoton imaging of the rapidly developing and relati

36 ng the in vivo invasion assay and intravital multiphoton imaging of tumor cell streaming.

37 We developed an in vivo multiphoton imaging paradigm to study alpha-synuclein ag

38 Moreover, in vivo multiphoton imaging revealed that deafening-induced chan

39 Intravital multiphoton imaging revealed that inhibition of CSF1R in

40 Multiphoton imaging revealed that paxillin-deficient neu

41 Live multiphoton imaging shows that selection is based on the

42 In brain slices of rat PFC, we employed multiphoton imaging simultaneously with whole-cell elect

43 n combination with in vivo pharmacologic and multiphoton imaging strategies to systematically test de

44 Multiphoton imaging suggested that most microspheres wer

45 e further demonstrate how this high-speed 3D multiphoton imaging system can be used to study neuronal

46 d close to the objective (possible only in a multiphoton imaging system) improves system sensitivity

47 Intravital studies using multiphoton imaging techniques can now be conducted to i

48 We demonstrate, using multiphoton imaging, that the arrangement of SMCs become

49 erial EM cell reconstruction, and time-lapse multiphoton imaging to characterize the molecular and mo

50 this hypothesis, we developed methods using multiphoton imaging to detect both neurofibrillary patho

51 However, using in vivo multiphoton imaging to observe tangles and activation of

52 lectrocardiography recordings and high-speed multiphoton imaging, to assess Ca(2+) handling, revealed

53 Using in vivo longitudinal multiphoton imaging, we found orchestrated activity-depe

54 Using intracranial multiphoton imaging, we found that infusion of 100 ng of

55 By intravital multiphoton imaging, we found that the motility of CD4(+

56 transgenic mouse models of AD together with multiphoton imaging, we measured neuronal calcium in ind

57 Using multiphoton imaging, we show a direct association betwee

58 Using multiphoton imaging, we show that dopamine depletion lea

59 Using electrophysiology with concurrent multiphoton imaging, we show that layer 6 pyramidal cell