Extended focus imaging in digital holographic microscopy: a review

Matrecano, Marcella; Paturzo, Melania; Ferraro, Pietro

doi:10.1117/1.oe.53.11.112317

Cited by 40 publications

(16 citation statements)

References 70 publications

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“…The rotation angle is well distributed so that we need light diffraction on a large angle as well as on a small angle. Extended focus imaging in digital holographic microscopy also requires exact light diffraction for a tilted plane [21].…”

Section: Discussionmentioning

confidence: 99%

Exact light propagation between rotated planes using non-uniform sampling and angular spectrum method

Kim

Ryu

et al. 2015

Optics Communications

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Section: Discussionmentioning

confidence: 99%

Exact light propagation between rotated planes using non-uniform sampling and angular spectrum method

Kim

Ryu

et al. 2015

Optics Communications

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“…Although size is a well-established metric, we introduce maximum pixel intensity as a useful metric able to differentiate drug resistant cells from the parent cell line. This approach differs from prior methods that depend on high magnification [23] or absolute measures of refractive index [5,40,51,52] and are inherently low throughput. Our approach relies on comparatively coarse metrics, but substantially higher throughput that is still able to direct interesting biological observations.…”

Section: Discussionmentioning

confidence: 99%

Label-free fingerprinting of tumor cells in bulk flow using inline digital holographic microscopy

Singh

Ahrens

et al. 2017

Biomed. Opt. Express

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Large-scale and label-free phenotyping of cells holds great promise in medicine, especially in cancer diagnostics and prognosis. Here, we introduce inline digital holography microscopy for volumetric imaging of cells in bulk flow and fingerprinting of flowing tumor cells based on two metrics, in-focus scattered intensity and cell diameter. Using planar distribution of immobilized particles, we identify the optimal recording distance and microscope objective magnification that minimizes the error in measurement of particle position, size and scattered intensity. Using the optimized conditions and the two metrics, we demonstrate the capacity to enumerate and fingerprint more than 100,000 cells. Finally, we highlight the power of our label-free and high throughput technology by characterizing breast tumor cell lines with different metastatic potentials and distinguishing drug resistant ovarian cancer cells from their parental cell line.

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“…Because of mutual restriction of resolution, magnification and DOF of MVS, DOF of MVS is too narrow to obtain the information of wide depth under high resolution and high magnification. 2,25 In order to obtain microscopic image containing complete surface of microparts, MVTS technique, whose schematic is shown in Figure 1, is used. From Figure 1, PPP is used to control the in-focus plane of MVS to perform MVTS along the optical axis (Z-axis) of microscope to obtain MVTS images at positions of MVTS.…”

Section: Microscopic Vision Tomographic Scanning (Mvts) Image Arraymentioning

confidence: 99%

Depth estimation method of surface of micropart in microassembly space based on microscopic vision tomographic scanning images

Wang

Qiang

2021

Journal of Microscopy

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Three-dimensional (3D) morphology of microparts has an important influence on performance of microassembly system that mainly assembles microparts in millimetre and micron scale. Because 3D morphology of microparts cannot be accurately obtained by conventional microscopic vision system, a depth estimation method of surface of micropart in microassembly space based on microscopic vision tomographic scanning (MVTS) images is proposed in this paper. The proposed method uses the positions of pixels with the largest focus values in MVTS image to construct the isodepth contours of surface of micropart and obtains the depth values of micropart's surface at the positions of MVTS by assigning depth values to corresponding isodepth contours. The MVTS images are obtained by MVTS and pixels with the largest focus values in MVTS image are obtained by focus measurement of MVTS images of micropart in microassembly space. On these bases, 3D spatial interpolation method is applied to map depth value of space between adjacent isodepth contours and to obtain depth values of all surface of micropart. Simulation experiments are carried out to verify the proposed method by generating simulated MVTS image array from two simulation objects, and the influence parameters of the proposed method are analysed. In established experimental setup of microassembly that can realise MVTS, experimental verification for the proposed depth estimation method are carried out by using cone cavity and end jaws of microgripper. 3D morphologies of depth maps of cone cavity and end jaws of microgripper are registered with their respective CAD models using iterative nearest point registration algorithm to quantify accuracy of depth estimation. The research results show that 3D morphology of micropart can be obtained by the proposed method and has better accuracy than those by conventional shape from focus method. This method provides a new way to obtain the morphology of microparts and lays a foundation for improving

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Extended focus imaging in digital holographic microscopy: a review

Cited by 40 publications

References 70 publications

Exact light propagation between rotated planes using non-uniform sampling and angular spectrum method

Exact light propagation between rotated planes using non-uniform sampling and angular spectrum method

Label-free fingerprinting of tumor cells in bulk flow using inline digital holographic microscopy

Depth estimation method of surface of micropart in microassembly space based on microscopic vision tomographic scanning images

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