Plane Imaging(平面成像)研究综述
Plane Imaging 平面成像 - We administered DEFINITY (LantheusR ) as an ultrasound enhancing agent along with bi-plane imaging (Panel A and Video 2). [1] Two-dimensional fluoroscopic imaging allows measurement of small magnitude humeral head translations that are prone to errors due to optical distortion, out-of-plane imaging, repeated manual identification of landmarks, and magnification. [2] To overcome this trade-off in 4-D imaging, we developed a holographic two-photon microscope for dual-plane imaging. [3] Comparison between optical setups demonstrate improved resilience to motion artifacts in sparsely labeled samples using Bessel beams, increased signal-to-noise ratio and cell-count using low numerical aperture Gaussian beams and nuclear GCaMP, and more uniform spatial sampling with temporal focusing versus multi-plane imaging. [4] We have developed a miniature two-photon microscope equipped with an axial scanning mechanism and a long-working-distance miniature objective to enable multi-plane imaging over a volume of 420 × 420 × 180 μm 3 at a lateral resolution of ~1 μm. [5] We detail the first reported use of biplane imaging using a portable ultrasound probe for difficult vascular access to increase first past success, efficiency, safety, and sterility during the coronavirus disease 2019 (COVID-19) pandemic. [6] The proposed device is anticipated to find applications in multi-plane imaging, optical tomography technique, optical data storage, and so on. [7] Our system has the advantages of multi-plane imaging with high axial sensitivity and high optical sectioning ability. [8] OBJECTIVE To evaluate the shape and area of the LVOT with conventional 2D diameter, short axis cross-sectional planimetry with biplane imaging and 3D multiplane reconstruction in patients undergoing cardiac surgery with transoesophageal echocardiography (TOE). [9] 2%) were treated via a unilateral transpedicular approach with the help of biplane imaging and under anesthesia. [10] Over the past decade the miniscope platform has expanded to include simultaneous optogenetic capabilities, electrically-tunable lenses that enable multi-plane imaging, color-corrected optics, and an integrated data acquisition platform that streamlines multimodal experiments. [11] Here, we develop an algorithm for axial motion correction for non-ratiometric calcium indicators taking advantage of simultaneous multi-plane imaging. [12] In this work, we proposed a bifocal metalens that can realize switchable multiplane imaging, controlled by changing the polarization state of an incident light. [13] Here we compare SALM, off-focus imaging and the most commonly used 3D SMLM techniques, namely cylindrical lens and biplane imaging, regarding 3D localization in close proximity to the coverslip. [14] The method is enabled by laser surgery, a microrobotic arm for controlling forceps for dissection assistance, an automated feeding robot, as well as volumetric, simultaneous multiplane imaging. [15] However, direct in-plane imaging of micro-objects with surface plasmon waves suffers from the lack of simple, two-dimensional lenses, mirrors, and other optical elements. [16] The spatial light modulator is used to achieve fast switching between different imaging planes in multi-plane imaging and correct for intrinsic optical aberrations associated with this imaging scheme. [17] Objective To explore the feasibility of real-time three-dimensional ultrasound Xplane imaging in quantifying left and right atrial diastolic maximal volume (LAVmax, RAVmax) and evaluating cardiac diastolic function in fetuses with cardiac disease in second and later trimesters. [18] Figure 1 Simultaneous multiplane imaging of two-dimensional transoesophageal echocardiography images (A) and three-dimensional transoesophageal echocardiography images in systole (C) and diastole (D) on admission. [19] Biplane imaging of LVOT allows direct planimetry of LVOT area. [20] In May 2015, the fast mode innovation for Airyscan combines illumination shaping with pinhole-plane imaging that enhances acquisition speeds by four times while simultaneously increasing SNR and resolution overcoming the traditional compromises of LSM imaging. [21] RESULTS: Bi-plane imaging had an average difference in mean contrast use of -15. [22] Previous work has investigated the use of 3D ultrasound and 2D in-plane imaging to track needle insertions but faced barriers to successful clinical translation. [23] To address this issue, we developed a variant of confocal microscopy that provides simultaneous multiplane imaging over large field of view and at video rate. [24] Comparison between optical setups demonstrate improved resilience to motion artifacts in sparsely labeled samples using Bessel beams, increased signal-to-noise ratio and cell-count using low numerical aperture Gaussian beams and nuclear GCaMP, and more uniform spatial sampling with temporal focusing versus multi-plane imaging. [25] Earth observation technology and applications are migrating from just plane imaging in a few spectral bands towards intensive spectral imaging. [26]我们使用 DEFINITY (LantheusR) 作为超声增强剂以及双平面成像(图 A 和视频 2)。 [1] 二维透视成像允许测量由于光学畸变、平面外成像、重复手动识别标志和放大而容易出错的小幅度肱骨头平移。 [2] 为了克服 4-D 成像中的这种权衡,我们开发了一种用于双平面成像的全息双光子显微镜。 [3] 光学设置之间的比较表明,使用贝塞尔光束在稀疏标记的样本中提高了对运动伪影的弹性,使用低数值孔径高斯光束和核 GCaMP 提高了信噪比和细胞计数,以及时间聚焦与多点聚焦相比更均匀的空间采样平面成像。 [4] 我们开发了一种配备轴向扫描机构和长工作距离微型物镜的微型双光子显微镜,可以在约 1 μm 的横向分辨率下实现 420 × 420 × 180 μm 3 的体积上的多平面成像。 [5] 我们详细介绍了首次报道的使用便携式超声探头对难以进入血管的双平面成像的使用,以在 2019 年冠状病毒病 (COVID-19) 大流行期间提高首次过去的成功率、效率、安全性和无菌性。 [6] 该装置有望在多平面成像、光学断层扫描技术、光学数据存储等方面得到应用。 [7] 我们的系统具有多平面成像、高轴向灵敏度和高光学切片能力的优点。 [8] 客观的 采用常规 2D 直径、双平面成像短轴横截面平面测量和 3D 多平面重建评估 LVOT 的形状和面积,用于接受经食道超声心动图 (TOE) 心脏手术的患者。 [9] 2%)在双平面成像和麻醉下通过单侧经椎弓根入路进行治疗。 [10] 在过去十年中,微型显微镜平台已扩展至包括同步光遗传学功能、支持多平面成像的电可调镜头、颜色校正光学器件以及简化多模态实验的集成数据采集平台。 [11] 在这里,我们开发了一种利用同时多平面成像的非比例钙指标的轴向运动校正算法。 [12] 在这项工作中,我们提出了一种双焦元透镜,可以通过改变入射光的偏振状态来实现可切换的多平面成像。 [13] 在这里,我们比较了 SALM、离焦成像和最常用的 3D SMLM 技术,即柱面透镜和双平面成像,关于靠近盖玻片的 3D 定位。 [14] 该方法通过激光手术、用于控制解剖辅助镊子的微型机器人臂、自动喂食机器人以及体积、同时多平面成像来实现。 [15] 然而,使用表面等离子波对微物体进行直接平面内成像存在缺乏简单的二维透镜、镜子和其他光学元件的问题。 [16] 空间光调制器用于实现多平面成像中不同成像平面之间的快速切换,并校正与该成像方案相关的固有光学像差。 [17] 客观的 探讨实时三维超声 Xplane 成像在量化妊娠中期和晚期心脏病胎儿左右心房舒张期最大容积 (LAVmax, RAVmax) 和评估心脏舒张功能的可行性。 [18] 图 1 入院时二维经食道超声心动图 (A) 和三维经食道超声心动图 (C) 和舒张期 (D) 的同时多平面成像。 [19] LVOT 的双平面成像允许 LVOT 区域的直接平面测量。 [20] 2015 年 5 月,Airyscan 的快速模式创新将照明整形与针孔平面成像相结合,将采集速度提高了四倍,同时提高了 SNR 和分辨率,克服了 LSM 成像的传统妥协。 [21] 结果: 双平面成像在平均对比度使用方面的平均差异为 -15。 [22] 以前的工作已经研究了使用 3D 超声和 2D 平面内成像来跟踪针插入,但面临成功临床转化的障碍。 [23] 为了解决这个问题,我们开发了一种共聚焦显微镜的变体,可在大视场和视频速率下提供同时多平面成像。 [24] 光学设置之间的比较表明,使用贝塞尔光束在稀疏标记的样本中提高了对运动伪影的弹性,使用低数值孔径高斯光束和核 GCaMP 提高了信噪比和细胞计数,以及时间聚焦与多点聚焦相比更均匀的空间采样平面成像。 [25] 地球观测技术和应用正在从仅在几个光谱带中的平面成像转向密集的光谱成像。 [26]
light sheet microscopy 光片显微镜
Our experiment results indicate that the multi-planar light sheet microscopy system provides a novel and feasible method for three-dimensional selected plane imaging and low-phototoxicity in vivo imaging. [1] This talk will introduce a novel, recently developed, instrument that combines light sheet microscopy, optical trapping and multiplane imaging in a single platform capable of imaging 3D cultures of live cell over long time courses and mapping to these images the local mechanical properties of the material surrounding the cells. [2] Our instrument combines optical tweezers and multiplane imaging for 3D optical microrheology, with light sheet microscopy for 3D fluorescence imaging. [3]我们的实验结果表明,多平面光片显微系统为三维选择平面成像和低光毒性活体成像提供了一种新颖可行的方法。 [1] 本次演讲将介绍一种新型的、最近开发的仪器,该仪器将光片显微镜、光学捕获和多平面成像结合在一个平台上,能够长时间对活细胞的 3D 培养物进行成像,并将材料的局部机械性能映射到这些图像包围细胞。 [2] nan [3]
Focal Plane Imaging 焦平面成像
Through theoretical analysis, the SPR angle was retrieved from back focal plane imaging, which was highly correlated to the RI of the surrounding medium. [1] Millimeter wave (MMW) focal plane imaging systems based on traditional polymer lenses are generally of poor imaging quality. [2] Here, we design an high quality factor silicon metasurface for third harmonic generation and perform back focal plane imaging of the diffraction orders, which present a rich variety of polarization states. [3] To this end, we perform both back focal plane imaging and momentum-resolved spectroscopy measurements of the emission. [4] This paper presents a simple, yet effective demosaicking technique using polarization channel difference prior for polarization images captured by division of focal plane imaging sensors. [5] In this paper, we have carried out back-focal plane imaging to reveal that the IMs of 1DPCs can couple with surface bound excited dye molecules, with or without a BSW mode presence. [6] Angle-resolved ellipsometry with back focal plane imaging has been found to be of increasing importance in recent industrial sensing by virtue of its rich information provided at various incident and azimuthal angles. [7] We show that this additional focal plane imaging path only requires a small fraction of the total flux, while representing a robust solution to estimate the PyWFS OG. [8] While far-field methods, such as back-focal plane imaging, can be used to infer the directionality of angular radiation patterns, the advantage of our technique is that a single hologram contains information on both the amplitude and phase of the scattered light, allowing to reverse numerically the propagation of the electromagnetic field toward the source. [9] The unambiguous evidence of the dark trions is further obtained by directly resolving the radiation pattern of the dark trions through back focal plane imaging. [10] 6 μm and functions as a division of focal plane imaging mask. [11] In this report we design and synthesize deep blue emitting, quantum confined, perovskite nanoplates and analyze their optical properties by combining angular emission measurements with back focal plane imaging and correlating the results with physical characterization. [12] Through back-focal plane imaging, we analyze the far-field radiation pattern of the investigated emitters and derive a crossed-dipole emission, which is strongly aligned along one axis. [13]通过理论分析,从后焦平面成像中反演了 SPR 角,该角与周围介质的 RI 高度相关。 [1] 基于传统聚合物透镜的毫米波(MMW)焦平面成像系统通常成像质量较差。 [2] nan [3] nan [4] nan [5] nan [6] nan [7] nan [8] 虽然远场方法(例如后焦平面成像)可用于推断角辐射模式的方向性,但我们技术的优点是单个全息图包含有关散射光的幅度和相位的信息,允许以数值方式反转电磁场向源的传播。 [9] 通过后焦平面成像直接解析暗三元的辐射图,进一步获得暗三元的明确证据。 [10] 6 μm,用作焦平面成像掩模的划分。 [11] 在本报告中,我们设计和合成了深蓝色发射、量子限制、钙钛矿纳米板,并通过将角发射测量与后焦平面成像相结合并将结果与物理表征相关联来分析它们的光学特性。 [12] 通过后焦平面成像,我们分析了所研究发射器的远场辐射模式,并得出了交叉偶极子发射,该发射沿一个轴强烈排列。 [13]
Galactic Plane Imaging
We have developed a method to make a spectral-line-based survey of hot cores, which represent an important stage of high-mass star formation, and applied the method to the data of the FUGIN (FOREST Unbiased Galactic plane Imaging survey with the Nobeyama 45 m telescope) survey. [1] We also investigated the 18 unclassified Multi-Array Galactic Plane Imaging Survey (MAGPIS) candidate SNRs, newly confirming three as SNRs, reclassifying two as H uc(ii) regions, and exploring the unusual spectra and morphology of two others. [2] Herein, we present the 12CO (J=1-0) and 13CO (J=1-0) emission line observations via the FOREST Unbiased Galactic plane Imaging survey with the Nobeyama 45-m telescope (FUGIN) toward a Spitzer bubble N4. [3] Radio sky surveys of the Multi-Array Galactic Plane Imaging Survey (MAGPIS) and the Sydney University Molonglo Sky Survey (SUMSS) indicate these dense molecular clouds are associated with ultracompact HII (UCHII) regions and/or classical HII regions. [4]我们开发了一种基于谱线的热核心勘测方法,它代表了大质量恒星形成的一个重要阶段,并将该方法应用于 FUGIN(与 Nobeyama 一起进行的森林无偏银河平面成像勘测)的数据45 m 望远镜)调查。 [1] 我们还调查了 18 个未分类的多阵列银河平面成像测量 (MAGPIS) 候选信噪比,新确认三个为信噪比,将两个重新分类为 H uc(ii) 区域,并探索了另外两个不寻常的光谱和形态。 [2] 在这里,我们通过野边山 45 米望远镜 (FUGIN) 对斯皮策气泡 N4 进行的森林无偏银河平面成像调查,展示了 12CO (J=1-0) 和 13CO (J=1-0) 发射线观测结果。 [3] 多阵列银河平面成像调查 (MAGPIS) 和悉尼大学莫隆洛天空调查 (SUMSS) 的无线电天空调查表明,这些密集的分子云与超紧凑 HII (UCHII) 区域和/或经典 HII 区域有关。 [4]
Axial Plane Imaging 轴向平面成像
We propose and demonstrate an optical manipulation system that incorporates an axial plane imaging module. [1] Axial plane imaging techniques assessing the entire pelvic floor at first misinterpreted the nature of changes visible after childbirth6, but, just 1 year later, major trauma to the levator ani (avulsion) was first described in a review article commissioned by UOG’s Founding Editor, Stuart Campbell7. [2] This article reviews the chronological development of axial plane imaging and spinal deformity measurement. [3]我们提出并演示了一种包含轴向平面成像模块的光学操作系统。 [1] 最初评估整个盆底的轴向平面成像技术误解了分娩后可见变化的性质6,但仅仅一年后,UOG 创始编辑 Stuart 委托撰写的一篇评论文章首次描述了肛提肌的重大创伤(撕脱)坎贝尔 7. [2] 本文回顾了轴向平面成像和脊柱畸形测量的时间发展。 [3]
Fourier Plane Imaging
Back focal plane or Fourier plane imaging and spectroscopy techniques help to measure wavevector distribution not only from single molecules and single nanostructures but also from metasurfaces and metamaterials. [1] The dispersion of this hybrid component, characterized by using a Fourier plane imaging microscopy setup, is essentially achromatic over about 150 nm in the visible. [2]后焦平面或傅里叶平面成像和光谱技术不仅有助于测量来自单个分子和单个纳米结构的波矢量分布,还有助于测量来自超表面和超材料的波矢量分布。 [1] 这种混合成分的色散,以使用傅里叶平面成像显微镜装置为特征,在可见光中在约 150 nm 范围内基本上是消色差的。 [2]
plane imaging survey
We have developed a method to make a spectral-line-based survey of hot cores, which represent an important stage of high-mass star formation, and applied the method to the data of the FUGIN (FOREST Unbiased Galactic plane Imaging survey with the Nobeyama 45 m telescope) survey. [1] We also investigated the 18 unclassified Multi-Array Galactic Plane Imaging Survey (MAGPIS) candidate SNRs, newly confirming three as SNRs, reclassifying two as H uc(ii) regions, and exploring the unusual spectra and morphology of two others. [2] Herein, we present the 12CO (J=1-0) and 13CO (J=1-0) emission line observations via the FOREST Unbiased Galactic plane Imaging survey with the Nobeyama 45-m telescope (FUGIN) toward a Spitzer bubble N4. [3] Radio sky surveys of the Multi-Array Galactic Plane Imaging Survey (MAGPIS) and the Sydney University Molonglo Sky Survey (SUMSS) indicate these dense molecular clouds are associated with ultracompact HII (UCHII) regions and/or classical HII regions. [4]我们开发了一种基于谱线的热核心勘测方法,它代表了大质量恒星形成的一个重要阶段,并将该方法应用于 FUGIN(与 Nobeyama 一起进行的森林无偏银河平面成像勘测)的数据45 m 望远镜)调查。 [1] 我们还调查了 18 个未分类的多阵列银河平面成像测量 (MAGPIS) 候选信噪比,新确认三个为信噪比,将两个重新分类为 H uc(ii) 区域,并探索了另外两个不寻常的光谱和形态。 [2] 在这里,我们通过野边山 45 米望远镜 (FUGIN) 对斯皮策气泡 N4 进行的森林无偏银河平面成像调查,展示了 12CO (J=1-0) 和 13CO (J=1-0) 发射线观测结果。 [3] 多阵列银河平面成像调查 (MAGPIS) 和悉尼大学莫隆洛天空调查 (SUMSS) 的无线电天空调查表明,这些密集的分子云与超紧凑 HII (UCHII) 区域和/或经典 HII 区域有关。 [4]
plane imaging microscopy
Angle-dependent photoluminescence spectroscopy and Fourier-plane imaging microscopy show that the orientation of roughly spherical fac-tris(2-phenylpyridyl)iridium (Ir(ppy)3 ) is isotropic, whereas complexes that are oblate spheroids, fac-tris(mesityl-2-phenyl-1H-imidazole)iridium (Ir(mi)3 ) and fac-tris((3,5-dimethyl-[1,1'-biphenyl]-4-yl)-2-phenyl-1H-imidazole)iridium (Ir(mip)3 ), have a net horizontal alignment of their transition dipole moments. [1] The dispersion of this hybrid component, characterized by using a Fourier plane imaging microscopy setup, is essentially achromatic over about 150 nm in the visible. [2]角度相关的光致发光光谱和傅里叶平面成像显微镜表明,大致球形的 fac-tris(2-苯基吡啶基)铱 (Ir(ppy)3 ) 的取向是各向同性的,而扁平球体的配合物 fac-tris(mesityl- 2-苯基-1H-咪唑)铱(Ir(mi)3)和fac-tris((3,5-二甲基-[1,1'-联苯]-4-基)-2-苯基-1H-咪唑)铱 (Ir(mip)3 ) 的跃迁偶极矩净水平对齐。 [1] 这种混合成分的色散,以使用傅里叶平面成像显微镜装置为特征,在可见光中在约 150 nm 范围内基本上是消色差的。 [2]
plane imaging system
Millimeter wave (MMW) focal plane imaging systems based on traditional polymer lenses are generally of poor imaging quality. [1] Khoo Teck Puat Hospital cardiac catheterization lab has both single plane and biplane imaging systems. [2]基于传统聚合物透镜的毫米波(MMW)焦平面成像系统通常成像质量较差。 [1] Khoo Teck Puat 医院心导管实验室拥有单平面和双平面成像系统。 [2]
plane imaging technique
Axial plane imaging techniques assessing the entire pelvic floor at first misinterpreted the nature of changes visible after childbirth6, but, just 1 year later, major trauma to the levator ani (avulsion) was first described in a review article commissioned by UOG’s Founding Editor, Stuart Campbell7. [1] Henceforth, we developed a quasi-simultaneous multiplane imaging technique combining an acousto-optic deflector and static remote focusing to provide fast imaging of neurons from different axial positions inside the cortical layers without the need for mechanical disturbance of either the objective lens or the specimen. [2]最初评估整个盆底的轴向平面成像技术误解了分娩后可见变化的性质6,但仅仅一年后,UOG 创始编辑 Stuart 委托撰写的一篇评论文章首次描述了肛提肌的重大创伤(撕脱)坎贝尔 7. [1] 此后,我们开发了一种准同时多平面成像技术,结合了声光偏转器和静态远程聚焦,以提供来自皮质层内不同轴向位置的神经元的快速成像,而无需物镜或标本的机械干扰。 [2]