Phase imaging of cells by simultaneous dual-wavelength reflection digital holography

Khmaladze, Alexander; Kim, Myung; Lo, Chia Ming

doi:10.1364/oe.16.010900

Cited by 148 publications

(45 citation statements)

References 23 publications

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“…In particular, we present dynamic imaging data of semiconductor structures while being etched; epi-DPM reveals quantitatively the etch rate at each point in the image and each moment in time. We found this rate to vary significantly versus position and time with typical values in the range of 0-8 nm s 21 . Finally, we show that photochemical etching can be used in combination with epi-DPM imaging to controllably vary the etch rate across the sample and thereby fabricate 'gray-scale' structures, e.g., microlenses.…”

Section: Introductionmentioning

confidence: 77%

“…To exploit this feature, we imaged the topography of an n1 GaAs wafer while being etched with a solution of H 3 PO 4 :H 2 O 2 :H 2 O (see Supplementary Information for details on the processing steps). 23 We acquired 400 frames at 8.93 frames s 21 , for a total of 44.8 s. Our epi-DPM movie (Supplementary Movie) revealed that it took approximately 10 s for the etchant to diffuse into the field of view and begin etching. The montage in Figure 3a indicates the spatial inhomogeneity and the time evolution of the etching process.…”

Section: Monitoring Nanoscale Topography During Etchingmentioning

confidence: 99%

“…Note that at the image plane, we obtain a magnified replica of the field reflected by the sample. The diffraction grating had 300 grooves mm 21 , blazed at an angle to maximize the power in the first diffraction order. Lens L 3 is used to generate the Fourier transform of the image field at its back focal plane.…”

Section: Introductionmentioning

confidence: 99%

“…This method essentially averages out the effects of speckles. 21,22 It also dithers the image, which reduces the quantization error. The Monitoring nanoscale topography during etching C Edwards et al 2 resulting epi-DPM images revealed that the spatial noise floor dropped to 10.4 nm after adding the diffuser.…”

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confidence: 99%

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Optically monitoring and controlling nanoscale topography during semiconductor etching

et al. 2012

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We present epi-diffraction phase microscopy (epi-DPM) as a non-destructive optical method for monitoring semiconductor fabrication processes in real time and with nanometer level sensitivity. The method uses a compact Mach-Zehnder interferometer to recover quantitative amplitude and phase maps of the field reflected by the sample. The low temporal noise of 0.6 nm per pixel at 8.93 frames per second enabled us to collect a three-dimensional movie showing the dynamics of wet etching and thereby accurately quantify non-uniformities in the etch rate both across the sample and over time. By displaying a gray-scale digital image on the sample with a computer projector, we performed photochemical etching to define arrays of microlenses while simultaneously monitoring their etch profiles with epi-DPM.

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Section: Introductionmentioning

confidence: 77%

Section: Monitoring Nanoscale Topography During Etchingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Optically monitoring and controlling nanoscale topography during semiconductor etching

et al. 2012

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“…In recent years, as a result of new advances in light sources, detector arrays and computing power, quantitative phase imaging (QPI), in which optical path-length delays are measured at each point in the field of view, has become a very active field of study 9 . Whether involving holographic or non-holographic methods 10-16 , QPI presents new opportunities for studying cells and tissues non-invasively, quantitatively and without the need for staining or tagging [17][18][19][20][21][22][23] . Projection tomography using laser QPI has made use of ideas from X-ray imaging and enabled three-dimensional imaging of transparent structures [24][25][26] .…”

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confidence: 99%

White-light diffraction tomography of unlabelled live cells

et al. 2014

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We present a technique called white-light diffraction tomography (WDT) for imaging microscopic transparent objects such as live unlabelled cells. The approach extends diffraction tomography to white-light illumination and imaging rather than scattering plane measurements. Our experiments were performed using a conventional phase contrast microscope upgraded with a module to measure quantitative phase images. The axial dimension of the object was reconstructed by scanning the focus through the object and acquiring a stack of phase-resolved images. We reconstructed the threedimensional structures of live, unlabelled, red blood cells and compared the results with confocal and scanning electron microscopy images. The 350 nm transverse and 900 nm axial resolution achieved reveals subcellular structures at high resolution in Escherichia coli cells. The results establish WDT as a means for measuring three-dimensional subcellular structures in a non-invasive and label-free manner.A transparent object illuminated by an electromagnetic field generates a scattering pattern that carries specific information about its internal structure. Inferring this information from measurements of the scattered field, that is, solving the inverse scattering problem, is the fundamental principle that has allowed X-ray diffraction measurements to reveal the molecular-scale organization of crystals 1 and more recently, image cells with nanoscale resolution 2,3 . The scattered field is related to the spatially varying dielectric susceptibility of the scattering object by a transformation that simplifies considerably and, more importantly, becomes invertible, when the incident field is only weakly perturbed by the presence of the object. In this regime, the first-order Born approximation 4 and the Rytov approximation 5 have been used to unambiguously retrieve the three-dimensional spatial distribution of the dielectric constant. Implementation of inverse scattering requires knowledge of both the amplitude and phase of the scattered field. This obstacle, known as the phase problem, has been associated with X-ray diffraction measurement throughout its century-old history (for a review, see ref. 6).In 1969, Wolf proposed diffraction tomography as a reconstruction method combining the X-ray diffraction principle with optical holography 7 . Unlike X-rays, light at lower frequencies can be used in phase imaging measurements, as demonstrated by Gabor 8 . In recent years, as a result of new advances in light sources, detector arrays and computing power, quantitative phase imaging (QPI), in which optical path-length delays are measured at each point in the field of view, has become a very active field of study 9 . Whether involving holographic or non-holographic methods 10-16 , QPI presents new opportunities for studying cells and tissues non-invasively, quantitatively and without the need for staining or tagging [17][18][19][20][21][22][23] . Projection tomography using laser QPI has made use of ideas from X-ray imaging and enabled three-dimensional ...

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Label‐free high temporal resolution assessment of cell proliferation using digital holographic microscopy

Janicke¹,

Kårsnäs²,

Egelberg³

et al. 2017

Cytometry Pt A

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Cell proliferation assays are widely applied in biological sciences to understand the effect of drugs over time. However, current methods often assess cell population growth indirectly, that is, the cells are not actually counted. Instead other parameters, for example, the amount of protein, are determined. These methods often also demand phototoxic labels, have low temporal resolution, or employ end-point assays, and frequently are labor intensive. We have developed a robust and label-free kinetic cell proliferation assay with high temporal resolution for adherent cells using digital holographic microscopy (DHM), one of many quantitative phase microscopy techniques. As no labels or stains are required, and only very low intensity illumination is necessary, the technique allows for noninvasive continuous cell counting. Only two image processing settings were adjusted between cell lines, making the assay practical, user friendly, and free of user bias. The developed direct assay was validated by analyzing cell cultures treated with various concentrations of the anti-cancer drug etoposide, a well-established topoisomerase inhibitor that causes DNA damage and leads to programmed cell death. After treatment, the unstained adherent cells were nondestructively imaged every 30 min for 36 h inside a cell incubator. In the recorded time-lapse image sequences, individual cells were automatically identified to provide detailed growth curves and growth rate data of cell number, confluence, and average cell volume. Our results demonstrate how these parameters facilitate a deeper understanding of cell processes than what is achievable with current single-parameter and end-point methods. © 2017 International Society for Advancement of Cytometry.

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Phase imaging of cells by simultaneous dual-wavelength reflection digital holography

Cited by 148 publications

References 23 publications

Optically monitoring and controlling nanoscale topography during semiconductor etching

Optically monitoring and controlling nanoscale topography during semiconductor etching

White-light diffraction tomography of unlabelled live cells

Label‐free high temporal resolution assessment of cell proliferation using digital holographic microscopy

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