Your search keyword '"Holography methods"' showing total 73 results

1. High-resolution lensless holographic microscopy using a physics-aware deep network.

Author

Galande AS, Thapa V, Vijay A, and John R

Subjects

Humans, Deep Learning, Algorithms, Neural Networks, Computer, Quantitative Phase Imaging, Holography methods, Microscopy methods, Image Processing, Computer-Assisted methods

Abstract

Significance: Lensless digital inline holographic microscopy (LDIHM) is an emerging quantitative phase imaging modality that uses advanced computational methods for phase retrieval from the interference pattern. The existing end-to-end deep networks require a large training dataset with sufficient diversity to achieve high-fidelity hologram reconstruction. To mitigate this data requirement problem, physics-aware deep networks integrate the physics of holography in the loss function to reconstruct complex objects without needing prior training. However, the data fidelity term measures the data consistency with a single low-resolution hologram without any external regularization, which results in a low performance on complex biological data., Aim: We aim to mitigate the challenges with trained and physics-aware untrained deep networks separately and combine the benefits of both methods for high-resolution phase recovery from a single low-resolution hologram in LDIHM., Approach: We propose a hybrid deep framework (HDPhysNet) using a plug-and-play method that blends the benefits of trained and untrained deep models for phase recovery in LDIHM. The high-resolution phase is generated by a pre-trained high-definition generative adversarial network (HDGAN) from a single low-resolution hologram. The generated phase is then plugged into the loss function of a physics-aware untrained deep network to regulate the complex object reconstruction process., Results: Simulation results show that the SSIM of the proposed method is increased by 0.07 over the trained and 0.04 over the untrained deep networks. The average phase-SNR is elevated by 8.2 dB over trained deep models and 9.8 dB over untrained deep networks on the experimental biological cells (cervical cells and red blood cells)., Conclusions: We showed improved performance of the HDPhysNet against the unknown perturbation in the imaging parameters such as the propagation distance, the wavelength of the illuminating source, and the imaging sample compared with the trained network (HDGAN). LDIHM, combined with HDPhysNet, is a portable and technology-driven microscopy best suited for point-of-care cytology applications., (© 2024 The Authors.)

Published

2024

2. Single-beam digital holographic reconstruction: a phase-support enhanced complex wavefront on phase-only function for twin-image elimination.

Author

Kyeremah C, Weiss M, Kandel D, Haehn D, and Yelleswarapu C

Subjects

Signal-To-Noise Ratio, Microscopy methods, Holography methods, Algorithms, Image Processing, Computer-Assisted methods, Artifacts

Abstract

Significance: In in-line digital holographic microscopy (DHM), twin-image artifacts pose a significant challenge, and reduction or complete elimination is essential for object reconstruction., Aim: To facilitate object reconstruction using a single hologram, significantly reduce inaccuracies, and avoid iterative processing, a digital holographic reconstruction algorithm called phase-support constraint on phase-only function (PCOF) is presented., Approach: In-line DHM simulations and tabletop experiments employing the sliding-window approach are used to compute the arithmetic mean and variance of the phase values in the reconstructed image. A support constraint mask, through variance thresholding, effectively enabled twin-image artifacts., Results: Quantitative evaluations using metrics such as mean squared error, peak signal-to-noise ratio, and mean structural similarity index show PCOF's superior capability in eliminating twin-image artifacts and achieving high-fidelity reconstructions compared with conventional methods such as angular spectrum and iterative phase retrieval methods., Conclusions: PCOF stands as a promising approach to in-line digital holographic reconstruction, offering a robust solution to mitigate twin-image artifacts and enhance the fidelity of reconstructed objects., (© 2024 The Authors.)

Published

2024

3. Off-axis digital lensless holographic microscopy based on spatially multiplexed interferometry.

Author

Picazo-Bueno JÁ, Ketelhut S, Schnekenburger J, Micó V, and Kemper B

Subjects

Humans, Image Processing, Computer-Assisted methods, Equipment Design, Holography instrumentation, Holography methods, Interferometry methods, Interferometry instrumentation, Quantitative Phase Imaging instrumentation, Quantitative Phase Imaging methods

Abstract

Significance: Digital holographic microscopy (DHM) is a label-free microscopy technique that provides time-resolved quantitative phase imaging (QPI) by measuring the optical path delay of light induced by transparent biological samples. DHM has been utilized for various biomedical applications, such as cancer research and sperm cell assessment, as well as for in vitro drug or toxicity testing. Its lensless version, digital lensless holographic microscopy (DLHM), is an emerging technology that offers size-reduced, lightweight, and cost-effective imaging systems. These features make DLHM applicable, for example, in limited resource laboratories, remote areas, and point-of-care applications., Aim: In addition to the abovementioned advantages, in-line arrangements for DLHM also include the limitation of the twin-image presence, which can restrict accurate QPI. We therefore propose a compact lensless common-path interferometric off-axis approach that is capable of quantitative imaging of fast-moving biological specimens, such as living cells in flow., Approach: We suggest lensless spatially multiplexed interferometric microscopy (LESSMIM) as a lens-free variant of the previously reported spatially multiplexed interferometric microscopy (SMIM) concept. LESSMIM comprises a common-path interferometric architecture that is based on a single diffraction grating to achieve digital off-axis holography. From a series of single-shot off-axis holograms, twin-image free and time-resolved QPI is achieved by commonly used methods for Fourier filtering-based reconstruction, aberration compensation, and numerical propagation., Results: Initially, the LESSMIM concept is experimentally demonstrated by results from a resolution test chart and investigations on temporal stability. Then, the accuracy of QPI and capabilities for imaging of living adherent cell cultures is characterized. Finally, utilizing a microfluidic channel, the cytometry of suspended cells in flow is evaluated., Conclusions: LESSMIM overcomes several limitations of in-line DLHM and provides fast time-resolved QPI in a compact optical arrangement. In summary, LESSMIM represents a promising technique with potential biomedical applications for fast imaging such as in imaging flow cytometry or sperm cell analysis., (© 2024 The Authors.)

Published

2024

4. Quantitative scoring of epithelial and mesenchymal qualities of cancer cells using machine learning and quantitative phase imaging.

Author

Lam V, Nguyen T, Bui V, Chung BM, Chang LC, Nehmetallah G, and Raub C

Subjects

Algorithms, Female, Gingiva cytology, Humans, MCF-7 Cells, Breast Neoplasms diagnostic imaging, Epithelial Cells pathology, Fibroblasts pathology, Holography methods, Machine Learning, Mesenchymal Stem Cells pathology

Abstract

Significance: We introduce an application of machine learning trained on optical phase features of epithelial and mesenchymal cells to grade cancer cells' morphologies, relevant to evaluation of cancer phenotype in screening assays and clinical biopsies., Aim: Our objective was to determine quantitative epithelial and mesenchymal qualities of breast cancer cells through an unbiased, generalizable, and linear score covering the range of observed morphologies., Approach: Digital holographic microscopy was used to generate phase height maps of noncancerous epithelial (Gie-No3B11) and fibroblast (human gingival) cell lines, as well as MDA-MB-231 and MCF-7 breast cancer cell lines. Several machine learning algorithms were evaluated as binary classifiers of the noncancerous cells that graded the cancer cells by transfer learning., Results: Epithelial and mesenchymal cells were classified with 96% to 100% accuracy. Breast cancer cells had scores in between the noncancer scores, indicating both epithelial and mesenchymal morphological qualities. The MCF-7 cells skewed toward epithelial scores, while MDA-MB-231 cells skewed toward mesenchymal scores. Linear support vector machines (SVMs) produced the most distinct score distributions for each cell line., Conclusions: The proposed epithelial-mesenchymal score, derived from linear SVM learning, is a sensitive and quantitative approach for detecting epithelial and mesenchymal characteristics of unknown cells based on well-characterized cell lines. We establish a framework for rapid and accurate morphological evaluation of single cells and subtle phenotypic shifts in imaged cell populations.

Published

2020

5. Common-path multimodal three-dimensional fluorescence and phase imaging system.

Author

Kumar M, Quan X, Awatsuji Y, Cheng C, Hasebe M, Tamada Y, and Matoba O

Subjects

Holography methods, Multimodal Imaging, Bryopsida cytology, Imaging, Three-Dimensional, Optical Imaging

Abstract

A stable multimodal system is developed by combining two common-path digital holographic microscopes (DHMs): coherent and incoherent, for simultaneous recording and retrieval of three-dimensional (3-D) phase and 3-D fluorescence imaging (FI), respectively, of a biological specimen. The 3-D FI is realized by a single-shot common-path off-axis fluorescent DHM developed recently by our group. In addition, we accomplish, the phase imaging by another single-shot, highly stable common-path off-axis DHM based on a beam splitter. In this DHM configuration, a beam splitter is used to divide the incoming object beam into two beams. One beam serves as the object beam carrying the useful information of the object under study, whereas another beam is spatially filtered at its Fourier plane by using a pinhole and it serves as a reference beam. This DHM setup, owing to a common-path geometry, is less vibration-sensitive and compact, having a similar field of view but with high temporal phase stability in comparison to a two-beam Mach-Zehnder-type DHM. The performance of the proposed common-path DHM and the multimodal system is verified by conducting various experiments on fluorescent microspheres and fluorescent protein-labeled living cells of the moss Physcomitrella patens. Moreover, the potential capability of the proposed multimodal system for 3-D live fluorescence and phase imaging of the fluorescent beads is also demonstrated. The obtained experimental results corroborate the feasibility of the proposed multimodal system and indicate its potential applications for the analysis of functional and structural behaviors of a biological specimen and enhancement of the understanding of physiological mechanisms and various biological diseases.

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Published

2020

6. Single-shot two-frame π-shifted spatially multiplexed interference phase microscopy.

Author

Trusiak M, Picazo-Bueno JA, Patorski K, Zdańkowski P, and Mico V

Subjects

Algorithms, Cell Line, Tumor, Humans, Male, Prostatic Neoplasms pathology, Holography methods, Image Processing, Computer-Assisted methods, Microscopy, Interference methods

Abstract

Single-shot, two-frame, π-shifted spatially multiplexed interference microscopy (π-SMIM) is presented as an improvement to previous SMIM implementations, introducing a versatile, robust, fast, and accurate method for cumbersome, noisy, and low-contrast phase object analysis. The proposed π-SMIM equips a commercially available nonholographic microscope with a high-speed (video frame rate) enhanced quantitative phase imaging (QPI) capability by properly placing a beam-splitter in the microscope embodiment to simultaneously (in a single shot) record two holograms mutually phase shifted by π radians at the expense of reducing the field of view. Upon subsequent subtractive superimposition of holograms, a π-hologram is generated with reduced background and improved modulation of interference fringes. These features determine superior phase retrieval quality, obtained by employing the Hilbert spiral transform on the π-hologram, as compared with a single low-quality (low signal-to-noise ratio) hologram analysis. In addition, π-SMIM enables accurate in-vivo analysis of high dynamic range phase objects, otherwise measurable only in static regime using time-consuming phase-shifting. The technique has been validated utilizing a 20  ×    /  0.46 NA objective in a regular Olympus BX-60 upright microscope for QPI of different lines of prostate cancer cells and flowing microbeads.

Published

2019

7. Biodynamic optical assay for embryo viability.

Author

Li Z, Ehmke N, Lorenzo IM, Machaty Z, and Nolte D

Subjects

Adenosine Triphosphate metabolism, Animals, Swine, Biological Assay methods, Embryo, Mammalian diagnostic imaging, Holography methods, Image Processing, Computer-Assisted methods, Imaging, Three-Dimensional methods, Microscopy methods, Reproductive Techniques, Assisted

Abstract

Early stage porcine parthenogenetic embryos were evaluated for metabolic activity using a biodynamic microscope (BDM) that images dynamic light scattering using low-coherence digital holography. The microscope has a 45-deg illumination configuration that reduces specular background for the imaging of small translucent samples. The off-axis illumination is compatible with coherence-gated imaging because of volumetric light scattering in which the coherence plane is tilted at half the illumination angle in a three-dimensional tissue target. The BDM was used to profile the viability of porcine parthenotes with normal and with inhibited mitochondrial adenosine triphosphate (ATP) production using Doppler fluctuation spectroscopy. The ATP concentrations in the parthenotes, which are indicative of developmental potential, were validated by a conventional bioluminescence assay. Biodynamic classifications achieved ∼80  %   accuracy correlating sample ATP treatment, providing a quick, label-free surrogate measurement to replace invasive metabolic assays as a candidate for evaluating quality of early embryos in the assisted reproductive technology setting.

Published

2019

8. Methamphetamine-induced apoptosis in glial cells examined under marker-free imaging modalities.

Author

D'Brant LY, Desta H, Khoo TC, Sharikova AV, Mahajan SD, and Khmaladze A

Subjects

Animals, Cell Line, Tumor, Equipment Design, Holography methods, Nanotechnology, Neuroglia drug effects, Rats, Spectrum Analysis, Raman, Apoptosis drug effects, Imaging, Three-Dimensional methods, Methamphetamine pharmacology, Microscopy methods

Abstract

We used phase microscopy and Raman spectroscopic measurements to assess the response of in vitro rat C6 glial cells following methamphetamine treatment in real time. Digital holographic microscopy (DHM) and three-dimensional (3-D) tomographic nanoscopy allow measurements of live cell cultures, which yield information about cell volume changes. Tomographic phase imaging provides 3-D information about the refractive index distribution associated with the morphology of biological samples. DHM provides similar information, but for a larger population of cells. Morphological changes in cells are associated with alterations in cell cycle and initiation of cell death mechanisms. Raman spectroscopy measurements provide information about chemical changes within the cells. Our Raman data indicate that the chemical changes in proteins preceded morphological changes, which were seen with DHM. Our study also emphasizes that tomographic phase imaging, DHM, and Raman spectroscopy are imaging tools that can be utilized for noninvasive simultaneous monitoring of morphological and chemical changes in cells during apoptosis and can also be used to monitor other dynamic cell processes.

Published

2019

9. Large field-of-view phase and fluorescence mesoscope with microscopic resolution.

Author

de Kernier I, Ali-Cherif A, Rongeat N, Cioni O, Morales S, Savatier J, Monneret S, and Blandin P

Subjects

Algorithms, Cell Line, Tumor, Cytological Techniques instrumentation, Cytological Techniques methods, Equipment Design, Holography instrumentation, Humans, Image Processing, Computer-Assisted, Microscopy, Fluorescence instrumentation, Holography methods, Microscopy, Fluorescence methods

Abstract

Phase and fluorescence are complementary contrasts that are commonly used in biology. However, the coupling of these two modalities is traditionally limited to high magnification and complex imaging systems. For statistical studies of biological populations, a large field-of-view is required. We describe a 30  mm2 field-of-view dual-modality mesoscope with a 4-μm resolution. The potential of the system to address biological questions is illustrated on white blood cell numeration in whole blood and multiwavelength imaging of the human osteosarcoma (U2-OS) cells.

Published

2019

10. Fast and improved bioimaging via temporal focusing multiphoton excitation microscopy with binary digital-micromirror-device holography.

Author

Sie YD, Chang CY, Lin CY, Chang NS, Campagnola PJ, and Chen SJ

Subjects

Animals, COS Cells, Chlorocebus aethiops, Equipment Design, Holography instrumentation, Lasers, Microscopy, Fluorescence, Multiphoton instrumentation, Holography methods, Image Processing, Computer-Assisted methods, Microscopy, Fluorescence, Multiphoton methods

Abstract

Conventional temporal focusing-based multiphoton excitation microscopy (TFMPEM) can offer widefield optical sectioning with an axial excitation confinement of a few microns. To improve the axial confinement of TFMPEM, a binary computer-generated Fourier hologram (CGFH) via a digital-micromirror-device (DMD) was implemented to intrinsically improve the axial confinement by filling the back-focal aperture of the objective lens. Experimental results show that the excitation focal volume can be condensed and the axial confinement improved about 24% according to the DMD holography. In addition, pseudouniform MPE can be achieved using two complementary CGFHs with rapid pulse-width modulation switching via the DMD. Furthermore, bioimaging of CV-1 in origin with SV40 genes-7 cells demonstrates that the TFMPEM with binary DMD holography can improve image quality by enhancing axial excitation confinement and rejecting out-of-focus excitation., ((2018) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE).)

Published

2018

11. Three-dimensional quantitative phase imaging of blood coagulation structures by optical projection tomography in flow cytometry using digital holographic microscopy.

Author

Funamizu H and Aizu Y

Subjects

Image Processing, Computer-Assisted methods, Blood Coagulation physiology, Flow Cytometry methods, Holography methods, Imaging, Three-Dimensional methods, Microscopy methods, Tomography, Optical methods

Abstract

Blood coagulation is an important role in the hemostasis process. In the observation using microscopies, an aggregation structure of red blood cells indicates the degree of blood coagulation. Recently, it has been proposed that digital holographic microscopy (DHM) is a powerful tool for biomedical cell imaging on the basis of quantitative phase information. DHM has the advantage in that the real-time and three-dimensional (3-D) quantitative phase imaging can be realized in the wide field of view, which means that the 3-D morphological parameters of biological cells without a staining process are obtained in real time. We report the complete 3-D quantitative phase imaging of blood coagulation structures by optical projection tomography in a flow cytometry using DHM.

Published

2018

12. Combined high-speed holographic shape and full-field displacement measurements of tympanic membrane.

Author

Razavi P, Tang H, Rosowski JJ, Furlong C, and Cheng JT

Subjects

Acoustic Stimulation methods, Humans, Vibration, Holography methods, Interferometry methods, Tympanic Membrane physiology

Abstract

The conical shape of the tympanic membrane (TM or eardrum) plays an important role in its function, such that variations in shape alter the acoustically induced motions of the TM. We present a method that precisely determines both shape and acoustically induced transient response of the entire TM using the same optics and maintaining the same coordinate system, where the TM transient displacements due to a broadband acoustic click excitation (50-μs impulse) and the shape are consecutively measured within <200  ms. Interferograms gathered with continuous high-speed (>2  kHz) optical phase sampling during a single 100-ms wavelength tuning ramp allow precise and rapid reconstructions of the TM shape at varied resolutions (50 to 200  μm). This rapid acquisition of full-field displacements and shape is immune to slow disturbances introduced by breathing or heartbeat of live subjects. Knowledge of TM shape and displacements enables the estimation of surface normal displacements regardless of the orientation of the TM within the measurement system. The proposed method helps better define TM mechanics and provides TM structure and function information useful for the diagnosis of ear disease.

Published

2018

13. Automated classification of cell morphology by coherence-controlled holographic microscopy.

Author

Strbkova L, Zicha D, Vesely P, and Chmelik R

Subjects

Algorithms, Humans, Pattern Recognition, Automated, Cells classification, Cells cytology, Holography methods, Microscopy methods

Abstract

In the last few years, classification of cells by machine learning has become frequently used in biology. However, most of the approaches are based on morphometric (MO) features, which are not quantitative in terms of cell mass. This may result in poor classification accuracy. Here, we study the potential contribution of coherence-controlled holographic microscopy enabling quantitative phase imaging for the classification of cell morphologies. We compare our approach with the commonly used method based on MO features. We tested both classification approaches in an experiment with nutritionally deprived cancer tissue cells, while employing several supervised machine learning algorithms. Most of the classifiers provided higher performance when quantitative phase features were employed. Based on the results, it can be concluded that the quantitative phase features played an important role in improving the performance of the classification. The methodology could be valuable help in refining the monitoring of live cells in an automated fashion. We believe that coherence-controlled holographic microscopy, as a tool for quantitative phase imaging, offers all preconditions for the accurate automated analysis of live cell behavior while enabling noninvasive label-free imaging with sufficient contrast and high-spatiotemporal phase sensitivity., ((2017) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE).)

Published

2017

14. Biodynamic imaging for phenotypic profiling of three-dimensional tissue culture.

Author

Sun H, Merrill D, An R, Turek J, Matei D, and Nolte DD

Subjects

Antineoplastic Agents, Phytogenic pharmacology, Cell Culture Techniques, Drug Screening Assays, Antitumor methods, Neoplasms, Paclitaxel pharmacology, Phenotype, Spheroids, Cellular drug effects, Spheroids, Cellular ultrastructure, Holography methods, Optical Imaging methods, Tissue Culture Techniques methods

Abstract

Three-dimensional (3-D) tissue culture represents a more biologically relevant environment for testing new drugs compared to conventional two-dimensional cancer cell culture models. Biodynamic imaging is a high-content 3-D optical imaging technology based on low-coherence interferometry and digital holography that uses dynamic speckle as high-content image contrast to probe deep inside 3-D tissue. Speckle contrast is shown to be a scaling function of the acquisition time relative to the persistence time of intracellular transport and hence provides a measure of cellular activity. Cellular responses of 3-D multicellular spheroids to paclitaxel are compared among three different growth techniques: rotating bioreactor (BR), hanging-drop (HD), and nonadherent (U-bottom, UB) plate spheroids, compared with ex vivo living tissues. HD spheroids have the most homogeneous tissue, whereas BR spheroids display large sample-to-sample variability as well as spatial heterogeneity. The responses of BR-grown tumor spheroids to paclitaxel are more similar to those of ex vivo biopsies than the responses of spheroids grown using HD or plate methods. The rate of mitosis inhibition by application of taxol is measured through tissue dynamics spectroscopic imaging, demonstrating the ability to monitor antimitotic chemotherapy. These results illustrate the potential use of low-coherence digital holography for 3-D pharmaceutical screening applications.

Published

2017

15. Human red blood cell recognition enhancement with three-dimensional morphological features obtained by digital holographic imaging.

Author

Jaferzadeh K and Moon I

Subjects

Algorithms, Cell Shape, Erythrocyte Indices, Hematologic Tests, Humans, Microscopy methods, Neural Networks, Computer, Pattern Recognition, Automated, Single-Cell Analysis methods, Erythrocytes cytology, Erythrocytes physiology, Holography methods, Imaging, Three-Dimensional methods

Abstract

The classification of erythrocytes plays an important role in the field of hematological diagnosis, specifically blood disorders. Since the biconcave shape of red blood cell (RBC) is altered during the different stages of hematological disorders, we believe that the three-dimensional (3-D) morphological features of erythrocyte provide better classification results than conventional two-dimensional (2-D) features. Therefore, we introduce a set of 3-D features related to the morphological and chemical properties of RBC profile and try to evaluate the discrimination power of these features against 2-D features with a neural network classifier. The 3-D features include erythrocyte surface area, volume, average cell thickness, sphericity index, sphericity coefficient and functionality factor, MCH and MCHSD, and two newly introduced features extracted from the ring section of RBC at the single-cell level. In contrast, the 2-D features are RBC projected surface area, perimeter, radius, elongation, and projected surface area to perimeter ratio. All features are obtained from images visualized by off-axis digital holographic microscopy with a numerical reconstruction algorithm, and four categories of biconcave (doughnut shape), flat-disc, stomatocyte, and echinospherocyte RBCs are interested. Our experimental results demonstrate that the 3-D features can be more useful in RBC classification than the 2-D features. Finally, we choose the best feature set of the 2-D and 3-D features by sequential forward feature selection technique, which yields better discrimination results. We believe that the final feature set evaluated with a neural network classification strategy can improve the RBC classification accuracy.

Published

2016

16. Investigation on dynamics of red blood cells through their behavior as biophotonic lenses.

Author

Memmolo P, Merola F, Miccio L, Mugnano M, and Ferraro P

Subjects

Equipment Design, Holography instrumentation, Humans, Optical Imaging instrumentation, Cell Tracking methods, Erythrocytes cytology, Holography methods, Imaging, Three-Dimensional methods, Optical Imaging methods

Abstract

The possibility to adopt biological matter as photonic optical elements can open scenarios in biophotonics research. Recently, it has been demonstrated that a red blood cell (RBC) can be seen as an optofluidic microlens by showing its imaging capability as well as its focal tunability. Moreover, correlation between an RBC’s morphology and its behavior as a refractive optical element has been established and its exploitation for biomedical diagnostic purposes has been foreseen. In fact, any deviation from the healthy RBC morphology can be seen as additional aberration in the optical wavefront passing through the cell. By this concept, accurate localization of focal spots of RBCs can become very useful in the blood disorders identification. We investigate the three-dimensional positioning of such focal spots over time for samples with two different osmolarity conditions, i.e., when they assume discocyte and spherical shapes, respectively. We also demonstrate that a temporal variation of an RBC’s focal points along the optical axis is correlated to the temporal fluctuations in the RBC’s thickness maps. Furthermore, we show a sort of synchronization of the whole erythrocytes ensemble.

Published

2016

17. Digital holographic microscopy of phase separation in multicomponent lipid membranes.

Author

Farzam Rad V, Moradi AR, Darudi A, and Tayebi L

Subjects

Cholesterol chemistry, Equipment Design, Holography instrumentation, Microscopy instrumentation, Models, Biological, Phosphatidylcholines chemistry, Phospholipids chemistry, Holography methods, Imaging, Three-Dimensional methods, Lipid Bilayers chemistry, Microscopy methods

Abstract

Lateral in-homogeneities in lipid compositions cause microdomains formation and change in the physical properties of biological membranes. With the presence of cholesterol and mixed species of lipids, phospholipid membranes segregate into lateral domains of liquid-ordered and liquid-disordered phases. Coupling of two-dimensional intralayer phase separations and interlayer liquid-crystalline ordering in multicomponent membranes has been previously demonstrated. By the use of digital holographic microscopy (DHMicroscopy), we quantitatively analyzed the volumetric dynamical behavior of such membranes. The specimens are lipid mixtures composed of sphingomyelin, cholesterol, and unsaturated phospholipid, 1,2-dioleoyl-sn-glycero-3-phosphocholine. DHMicroscopy in a transmission mode is an effective tool for quantitative visualization of phase objects. By deriving the associated phase changes, three-dimensional information on the morphology variation of lipid stacks at arbitrary time scales is obtained. Moreover, the thickness distribution of the object at demanded axial planes can be obtained by numerical focusing. Our results show that the volume evolution of lipid domains follows approximately the same universal growth law of previously reported area evolution. However, the thickness of the domains does not alter significantly by time; therefore, the volume evolution is mostly attributed to the changes in area dynamics. These results might be useful in the field of membrane-based functional materials.

Published

2016

18. Quantitative phase imaging of live cells with near on-axis digital holographic microscopy using constrained optimization approach.

Author

Pandiyan VP, Khare K, and John R

Subjects

Algorithms, Fourier Analysis, Yeasts cytology, Holography methods, Image Processing, Computer-Assisted methods, Microscopy methods

Abstract

We demonstrate a single-shot near on-axis digital holographic microscope that uses a constrained optimization approach for retrieval of the complex object function in the hologram plane. The recovered complex object is back-propagated from the hologram plane to image plane using the Fresnel back-propagation algorithm. A numerical aberration compensation algorithm is employed for correcting the aberrations in the object beam. The reference beam angle is calculated automatically using the modulation property of Fourier transform without any additional recording. We demonstrate this approach using a United States Air Force (USAF) resolution target as an object on our digital holographic microscope. We also demonstrate this approach by recovering the quantitative phase images of live yeast cells, red blood cells and dynamics of live dividing yeast cells.

Published

2016

19. Spatially multiplexed interferometric microscopy with partially coherent illumination.

Author

Picazo-Bueno JÁ, Zalevsky Z, García J, Ferreira C, and Micó V

Subjects

Algorithms, Animals, Cell Line, Tumor cytology, Equipment Design, Erythrocytes cytology, Holography instrumentation, Humans, Lighting, Male, Microscopy, Interference instrumentation, Reproducibility of Results, Spermatozoa cytology, Swine, Holography methods, Image Processing, Computer-Assisted methods, Microscopy, Interference methods

Abstract

We have recently reported on a simple, low cost, and highly stable way to convert a standard microscope into a holographic one [Opt. Express 22, 14929 (2014)]. The method, named spatially multiplexed interferometric microscopy (SMIM), proposes an off-axis holographic architecture implemented onto a regular (nonholographic) microscope with minimum modifications: the use of coherent illumination and a properly placed and selected one-dimensional diffraction grating. In this contribution, we report on the implementation of partially (temporally reduced) coherent illumination in SMIM as a way to improve quantitative phase imaging. The use of low coherence sources forces the application of phase shifting algorithm instead of off-axis holographic recording to recover the sample’s phase information but improves phase reconstruction due to coherence noise reduction. In addition, a less restrictive field of view limitation (1/2) is implemented in comparison with our previously reported scheme (1/3). The proposed modification is experimentally validated in a regular Olympus BX-60 upright microscope considering a wide range of samples (resolution test, microbeads, swine sperm cells, red blood cells, and prostate cancer cells).

Published

2016

20. Lensless two-photon imaging through a multicore fiber with coherence-gated digital phase conjugation.

Author

Conkey DB, Stasio N, Morales-Delgado EE, Romito M, Moser C, and Psaltis D

Subjects

Endoscopes, Fiber Optic Technology instrumentation, Fluorescent Dyes, HCT116 Cells, Humans, Holography methods, Image Processing, Computer-Assisted methods, Optical Imaging instrumentation, Optical Imaging methods

Abstract

We performed near-diffraction limited two-photon fluorescence (TPF) imaging through a lensless, multicore-fiber (MCF) endoscope utilizing digital phase conjugation. The phase conjugation technique is compatible with commercially available MCFs with high core density. We demonstrate focusing of ultrashort pulses through an MCF and show that the method allows for resolution that is not limited by the MCF core spacing. We constructed TPF images of fluorescent beads and cells by digital scanning of the phase-conjugated focus on the target object and collection of the emitted fluorescence through the MCF.

Published

2016

21. Holographic analysis on deformation and restoration of malaria-infected red blood cells by antimalarial drug.

Author

Byeon H, Ha YR, and Lee SJ

Subjects

Antimalarials administration & dosage, Cell Size drug effects, Cell Tracking instrumentation, Cells, Cultured, Equipment Design, Equipment Failure Analysis, Erythrocytes drug effects, Holography methods, Humans, Microscopy, Phase-Contrast methods, Plasmodium falciparum drug effects, Reproducibility of Results, Sensitivity and Specificity, Treatment Outcome, Chloroquine administration & dosage, Erythrocytes pathology, Erythrocytes virology, Holography instrumentation, Microscopy, Phase-Contrast instrumentation, Plasmodium falciparum physiology

Abstract

Malaria parasites induce morphological, biochemical, and mechanical changes in red blood cells (RBCs). Mechanical variations are closely related to the deformability of individual RBCs. The deformation of various RBCs, including healthy and malaria-infected RBCs (iRBCs), can be directly observed through quantitative phase imaging (QPI). The effects of chloroquine treatment on the mechanical property variation of iRBCs were investigated using time-resolved holographic QPI of single live cells on a millisecond time scale. The deformabilities of healthy RBCs, iRBCs, and drug-treated iRBCs were compared, and the effect of chloroquine on iRBC restoration was experimentally examined. The present results are beneficial to elucidate the dynamic characteristics of iRBCs and the effect of the antimalarial drug on iRBCs.

Published

2015

22. Quantitative investigation of red blood cell three-dimensional geometric and chemical changes in the storage lesion using digital holographic microscopy.

Author

Jaferzadeh K and Moon I

Subjects

Cell Tracking instrumentation, Cell Tracking methods, Cells, Cultured, Equipment Design, Equipment Failure Analysis, Holography methods, Humans, Imaging, Three-Dimensional methods, Microscopy methods, Molecular Imaging instrumentation, Reproducibility of Results, Sensitivity and Specificity, Signal Processing, Computer-Assisted instrumentation, Blood Preservation, Erythrocytes chemistry, Erythrocytes pathology, Holography instrumentation, Imaging, Three-Dimensional instrumentation, Microscopy instrumentation

Abstract

Quantitative phase information obtained by digital holographic microscopy (DHM) can provide new insight into the functions and morphology of single red blood cells (RBCs). Since the functionality of a RBC is related to its three-dimensional (3-D) shape, quantitative 3-D geometric changes induced by storage time can help hematologists realize its optimal functionality period. We quantitatively investigate RBC 3-D geometric changes in the storage lesion using DHM. Our experimental results show that the substantial geometric transformation of the biconcave-shaped RBCs to the spherocyte occurs due to RBC storage lesion. This transformation leads to progressive loss of cell surface area, surface-to-volume ratio, and functionality of RBCs. Furthermore, our quantitative analysis shows that there are significant correlations between chemical and morphological properties of RBCs.

Published

2015

23. Holographic laser Doppler imaging of pulsatile blood flow.

Author

Bencteux J, Pagnoux P, Kostas T, Bayat S, and Atlan M

Subjects

Humans, Image Processing, Computer-Assisted, Interferometry, Pulsatile Flow physiology, Pulse methods, Skin, Holography methods, Laser-Doppler Flowmetry methods, Signal Processing, Computer-Assisted

Abstract

We report on wide-field imaging of pulsatile motion induced by blood flow using heterodyne holographic interferometry on the thumb of a healthy volunteer, in real time. Optical Doppler images were measured with green laser light by a frequency-shifted Mach-Zehnder interferometer in off-axis configuration. The recorded optical signal was linked to local instantaneous out-of-plane motion of the skin at velocities of a few hundreds of microns per second and compared to blood pulse monitored by plethysmoraphy during an occlusion-reperfusion experiment.

Published

2015

24. Incubator proof miniaturized Holomonitor to in situ monitor cancer cells exposed to green tea polyphenol and preosteoblast cells adhering on nanostructured titanate surfaces: validity of the measured parameters and their corrections.

Author

Peter B, Nador J, Juhasz K, Dobos A, Körösi L, Székács I, Patko D, and Horvath R

Subjects

Animals, Catechin pharmacology, Cell Adhesion drug effects, Cell Line, HeLa Cells, Humans, Mice, Neoplasms metabolism, Reproducibility of Results, Single-Cell Analysis methods, Titanium chemistry, Catechin analogs & derivatives, Cell Movement drug effects, Holography methods, Microscopy methods, Nanostructures chemistry, Tea chemistry

Abstract

The in situ observation of cell movements and morphological parameters over longer periods of time under physiological conditions is critical in basic cell research and biomedical applications. The quantitative phase-contrast microscope applied in this study has a remarkably small size, therefore it can be placed directly into a humidified incubator. Here, we report on the successful application of this M4 Holomonitor to observe cancer cell motility, motility speed, and migration in the presence of the green tea polyphenol, epigallocatechin gallate, as well as to monitor the adhesion of preosteoblast cells on nanostructured titanate coatings, relevant for biomedical applications. A special mechanical stage was developed to position the sample into that range of the optical arrangement where digital autofocusing works with high reproducibility and precision. By in-depth analyzing the obtained single cell morphological parameters, we show that the limited vertical resolution of the optical setup results in underestimated single cell contact area and volume and overestimated single cell averaged thickness. We propose a simple model to correct the recorded data to obtain more precise single cell parameters. We compare the results with the kinetic data recorded by a surface sensitive optical biosensor, optical waveguide lightmode spectroscopy.

Published

2015

25. Three-dimensional vibrometry of the human eardrum with stroboscopic lensless digital holography.

Author

Khaleghi M, Furlong C, Ravicz M, Cheng JT, and Rosowski JJ

Subjects

Acoustics, Algorithms, Cadaver, Computers, Hearing, Humans, Light, Membranes, Artificial, Models, Theoretical, Motion, Reproducibility of Results, Sound, Vibration, Holography methods, Imaging, Three-Dimensional methods, Interferometry methods, Stroboscopy instrumentation, Stroboscopy methods, Tympanic Membrane physiology

Abstract

The eardrum or tympanic membrane (TM) transforms acoustic energy at the ear canal into mechanical motions of the ossicles. The acousto-mechanical transformer behavior of the TM is determined by its shape, three-dimensional (3-D) motion, and mechanical properties. We have developed an optoelectronic holographic system to measure the shape and 3-D sound-induced displacements of the TM. The shape of the TM is measured with dual-wavelength holographic contouring using a tunable near IR laser source with a central wavelength of 780 nm. 3-D components of sound-induced displacements of the TM are measured with the method of multiple sensitivity vectors using stroboscopic holographic interferometry. To accurately obtain sensitivity vectors, a new technique is developed and used in which the sensitivity vectors are obtained from the images of a specular sphere that is being illuminated from different directions. Shape and 3-D acoustically induced displacement components of cadaveric human TMs at several excitation frequencies are measured at more than one million points on its surface. A numerical rotation matrix is used to rotate the original Euclidean coordinate of the measuring system in order to obtain in-plane and out-of-plane motion components. Results show that in-plane components of motion are much smaller (<20%) than the out-of-plane motions’ components.

Published

2015

26. Holographic fluorescence microscopy with incoherent digital holographic adaptive optics.

Author

Jang C, Kim J, Clark DC, Lee S, Lee B, and Kim MK

Subjects

Computer Simulation, Equipment Design, Holography instrumentation, Microscopy, Fluorescence instrumentation, Optics and Photonics instrumentation, Holography methods, Microscopy, Fluorescence methods

Abstract

Introduction of adaptive optics technology into astronomy and ophthalmology has made great contributions in these fields, allowing one to recover images blurred by atmospheric turbulence or aberrations of the eye. Similar adaptive optics improvement in microscopic imaging is also of interest to researchers using various techniques. Current technology of adaptive optics typically contains three key elements: a wavefront sensor, wavefront corrector, and controller. These hardware elements tend to be bulky, expensive, and limited in resolution, involving, for example, lenslet arrays for sensing or multiactuator deformable mirrors for correcting. We have previously introduced an alternate approach based on unique capabilities of digital holography, namely direct access to the phase profile of an optical field and the ability to numerically manipulate the phase profile. We have also demonstrated that direct access and compensation of the phase profile are possible not only with conventional coherent digital holography, but also with a new type of digital holography using incoherent light: selfinterference incoherent digital holography (SIDH). The SIDH generates a complex—i.e., amplitude plus phase—hologram from one or several interferograms acquired with incoherent light, such as LEDs, lamps, sunlight, or fluorescence. The complex point spread function can be measured using guide star illumination and it allows deterministic deconvolution of the full-field image. We present experimental demonstration of aberration compensation in holographic fluorescence microscopy using SIDH. Adaptive optics by SIDH provides new tools for improved cellular fluorescence microscopy through intact tissue layers or other types of aberrant media.

Published

2015

27. Dynamic phase differences based on quantitative phase imaging for the objective evaluation of cell behavior.

Author

Krizova A, Collakova J, Dostal Z, Kvasnica L, Uhlirova H, Zikmund T, Vesely P, and Chmelik R

Subjects

Animals, Cell Line, Cell Shape physiology, Osmotic Pressure physiology, Rats, Cytological Techniques methods, Holography methods, Microscopy methods

Abstract

Quantitative phase imaging (QPI) brought innovation to noninvasive observation of live cell dynamics seen as cell behavior. Unlike the Zernike phase contrast or differential interference contrast, QPI provides quantitative information about cell dry mass distribution. We used such data for objective evaluation of live cell behavioral dynamics by the advanced method of dynamic phase differences (DPDs). The DPDs method is considered a rational instrument offered by QPI. By subtracting the antecedent from the subsequent image in a time-lapse series, only the changes in mass distribution in the cell are detected. The result is either visualized as a two dimensional color-coded projection of these two states of the cell or as a time dependence of changes quantified in picograms. Then in a series of time-lapse recordings, the chain of cell mass distribution changes that would otherwise escape attention is revealed. Consequently, new salient features of live cell behavior should emerge. Construction of the DPDs method and results exhibiting the approach are presented. Advantage of the DPDs application is demonstrated on cells exposed to an osmotic challenge. For time-lapse acquisition of quantitative phase images, the recently developed coherence-controlled holographic microscope was employed.

Published

2015

28. Simultaneous full-field 3-D vibrometry of the human eardrum using spatial-bandwidth multiplexed holography.

Author

Khaleghi M, Guignard J, Furlong C, and Rosowski JJ

Subjects

Algorithms, Female, Humans, Middle Aged, Holography methods, Imaging, Three-Dimensional methods, Tympanic Membrane anatomy & histology, Tympanic Membrane physiology

Abstract

Holographic interferometric methods typically require the use of three sensitivity vectors in order to obtain three-dimensional (3-D) information. Methods based on multiple directions of illumination have limited applications when studying biological tissues that have temporally varying responses such as the tympanic membrane (TM). Therefore, to measure 3-D displacements in such applications, the measurements along all the sensitivity vectors have to be done simultaneously. We propose a multiple-illumination directions approach to measure 3-D displacements from a single-shot hologram that contains displacement information from three sensitivity vectors. The hologram of an object of interest is simultaneously recorded with three incoherently superimposed pairs of reference and object beams. The incident off-axis angles of the reference beams are adjusted such that the frequency components of the multiplexed hologram are completely separate. Because of the differences in the directions and wavelengths of the reference beams, the positions of each reconstructed image corresponding to each sensitivity vector are different. We implemented a registration algorithm to accurately translate individual components of the hologram into a single global coordinate system to calculate 3-D displacements. The results include magnitudes and phases of 3-D sound-induced motions of a human cadaveric TM at several excitation frequencies showing modal and traveling wave motions on its surface.

Published

2015

29. Three-dimensional counting of morphologically normal human red blood cells via digital holographic microscopy.

Author

Yi F, Moon I, and Lee YH

Subjects

Algorithms, Bayes Theorem, Humans, Erythrocytes classification, Erythrocytes cytology, Holography methods, Image Cytometry methods, Microscopy methods

Abstract

Counting morphologically normal cells in human red blood cells (RBCs) is extremely beneficial in the health care field. We propose a three-dimensional (3-D) classification method of automatically determining the morphologically normal RBCs in the phase image of multiple human RBCs that are obtained by off-axis digital holographic microscopy (DHM). The RBC holograms are first recorded by DHM, and then the phase images of multiple RBCs are reconstructed by a computational numerical algorithm. To design the classifier, the three typical RBC shapes, which are stomatocyte, discocyte, and echinocyte, are used for training and testing. Nonmain or abnormal RBC shapes different from the three normal shapes are defined as the fourth category. Ten features, including projected surface area, average phase value, mean corpuscular hemoglobin, perimeter, mean corpuscular hemoglobin surface density, circularity, mean phase of center part, sphericity coefficient, elongation, and pallor, are extracted from each RBC after segmenting the reconstructed phase images by using a watershed transform algorithm. Moreover, four additional properties, such as projected surface area, perimeter, average phase value, and elongation, are measured from the inner part of each cell, which can give significant information beyond the previous 10 features for the separation of the RBC groups; these are verified in the experiment by the statistical method of Hotelling's T-quare test. We also apply the principal component analysis algorithm to reduce the dimension number of variables and establish the Gaussian mixture densities using the projected data with the first eight principal components. Consequently, the Gaussian mixtures are used to design the discriminant functions based on Bayesian decision theory. To improve the performance of the Bayes classifier and the accuracy of estimation of its error rate, the leaving-one-out technique is applied. Experimental results show that the proposed method can yield good results for calculating the percentage of each typical normal RBC shape in a reconstructed phase image of multiple RBCs that will be favorable to the analysis of RBC-related diseases. In addition, we show that the discrimination performance for the counting of normal shapes of RBCs can be improved by using 3-D features of an RBC.

Published

2015

30. Digital adaptive optics line-scanning confocal imaging system.

Author

Liu C and Kim MK

Subjects

Computer Simulation, Equipment Design, Holography methods, Microscopy, Confocal methods, Models, Theoretical, Holography instrumentation, Microscopy, Confocal instrumentation, Optics and Photonics instrumentation

Abstract

A digital adaptive optics line-scanning confocal imaging (DAOLCI) system is proposed by applying digital holographic adaptive optics to a digital form of line-scanning confocal imaging system. In DAOLCI, each line scan is recorded by a digital hologram, which allows access to the complex optical field from one slice of the sample through digital holography. This complex optical field contains both the information of one slice of the sample and the optical aberration of the system, thus allowing us to compensate for the effect of the optical aberration, which can be sensed by a complex guide star hologram. After numerical aberration compensation, the corrected optical fields of a sequence of line scans are stitched into the final corrected confocal image. In DAOLCI, a numerical slit is applied to realize the confocality at the sensor end. The width of this slit can be adjusted to control the image contrast and speckle noise for scattering samples. DAOLCI dispenses with the hardware pieces, such as Shack–Hartmann wavefront sensor and deformable mirror, and the closed-loop feedbacks adopted in the conventional adaptive optics confocal imaging system, thus reducing the optomechanical complexity and cost. Numerical simulations and proof-of-principle experiments are presented that demonstrate the feasibility of this idea.

Published

2015

31. Coherence-controlled holographic microscopy enabled recognition of necrosis as the mechanism of cancer cells death after exposure to cytopathic turbid emulsion.

Author

Collakova J, Krizova A, Kollarova V, Dostal Z, Slaba M, Vesely P, and Chmelik R

Subjects

Cell Line, Tumor, Dichloroacetic Acid, Humans, Necrosis, Phospholipids, Cell Death physiology, Cytological Techniques methods, Holography methods, Microscopy methods, Neoplasms physiopathology

Abstract

Coherence-controlled holographic microscopy (CCHM) in low-coherence mode possesses a pronounced coherence gate effect. This offers an option to investigate the details of cellular events leading to cell death caused by cytopathic turbid emulsions. CCHM capacity was first assessed in model situations that showed clear images obtained with low coherence of illumination but not with high coherence of illumination. Then, the form of death of human cancer cells induced by treatment with biologically active phospholipids (BAPs) preparation was investigated. The observed overall retraction of cell colony was apparently caused by the release of cell-to-substratum contacts. This was followed by the accumulation of granules decorating the nuclear membrane. Then, the occurrence of nuclear membrane indentations signaled the start of damage to the integrity of the cell nucleus. In the final stage, cells shrunk and disintegrated. This indicated that BAPs cause cell death by necrosis and not apoptosis. An intriguing option of checking the fate of cancer cells caused by the anticipated cooperative effect after adding another tested substance sodium dichloroacetate to turbid emulsion is discussed on grounds of pilot experiments. Such observations should reveal the impact and mechanism of action of the interacting drugs on cell behavior and fate that would otherwise remain hidden in turbid milieu.

Published

2015

32. Quantitative phase imaging through scattering media by means of coherence-controlled holographic microscope.

Author

Kollarova V, Collakova J, Dostal Z, Vesely P, and Chmelik R

Subjects

Algorithms, Cell Line, Tumor, Computer Simulation, Humans, Light, Scattering, Radiation, Holography methods, Image Processing, Computer-Assisted methods, Microscopy methods

Abstract

A coherence-controlled holographic microscope (CCHM) enables quantitative phase imaging with coherent as well as incoherent illumination. The low spatially coherent light induces a coherence gating effect, which makes observation of samples possible also through scattering media. The paper describes theoretically and simulates numerically imaging of a two-dimensional object through a static scattering layer by means of CCHM, with the main focus on the quantitative phase imaging quality. The authors have investigated both strongly and weakly scattering media characterized by different amounts of ballistic and diffuse light. It is demonstrated that the phase information can be revealed also for the case of the static, strongly scattering layer. The dependence of the quality of imaging process on the spatial light coherence is demonstrated. The theoretical calculations and numerical simulations are supported by experimental data gained with a model phase object, as well as living carcinoma cells treated in an optically turbid emulsion.

Published

2015

33. Single-beam, dual-view digital holographic interferometry for biomechanical strain measurements of biological objects.

Author

Pantelić DV, Grujić DŽ, and Vasiljević DM

Subjects

Bicuspid physiology, Equipment Design, Finite Element Analysis, Humans, Image Processing, Computer-Assisted, Mastication physiology, Biomechanical Phenomena physiology, Holography instrumentation, Holography methods, Interferometry instrumentation, Interferometry methods

Abstract

We describe a method for dual-view biomechanical strain measurements of highly asymmetrical biological objects, like teeth or bones. By using a spherical mirror, we were able to simultaneously record a digital hologram of the object itself and the mirror image of its (otherwise invisible) rear side. A single laser beam was sufficient to illuminate both sides of the object, and to provide a reference beam. As a result, the system was mechanically very stable, enabling long exposure times (up to 2 min) without the need for vibration isolation. The setup is simple to construct and adjust, and can be used to interferometrically observe any object that is smaller than the mirror diameter. Parallel data processing on a CUDA-enabled (compute unified device architecture) graphics card was used to reconstruct digital holograms and to further correct image distortion. We used the setup to measure the deformation of a tooth due to mastication forces. The finite-element method was used to compare experimental results and theoretical predictions.

Published

2014

34. Full-field transient vibrometry of the human tympanic membrane by local phase correlation and high-speed holography.

Author

Dobrev I, Furlong C, Cheng JT, and Rosowski JJ

Subjects

Algorithms, Female, Humans, Middle Aged, Reproducibility of Results, Holography methods, Image Processing, Computer-Assisted methods, Signal Processing, Computer-Assisted, Tympanic Membrane physiology, Vibration

Abstract

Understanding the human hearing process would be helped by quantification of the transient mechanical response of the human ear, including the human tympanic membrane (TM or eardrum). We propose a new hybrid high-speed holographic system (HHS) for acquisition and quantification of the full-field nanometer transient (i.e., >10 kHz) displacement of the human TM. We have optimized and implemented a 2 þ 1 frame local correlation (LC) based phase sampling method in combination with a high-speed (i.e., >40 K fps) camera acquisition system. To our knowledge, there is currently no existing system that provides such capabilities for the study of the human TM. The LC sampling method has a displacement difference of <11 nm relative to measurements obtained by a four-phase step algorithm. Comparisons between our high-speed acquisition system and a laser Doppler vibrometer indicate differences of <10 μs. The high temporal (i.e., >40 kHz) and spatial (i.e., >100 k data points) resolution of our HHS enables parallel measurements of all points on the surface of the TM, which allows quantification of spatially dependent motion parameters, such as modal frequencies and acoustic delays. Such capabilities could allow inferring local material properties across the surface of the TM.

Published

2014

35. Two-step phase-shifting fluorescence incoherent holographic microscopy.

Author

Qin W, Yang X, Li Y, Peng X, Yao H, Qu X, and Gao BZ

Subjects

Fourier Analysis, Interferometry methods, Polymers chemistry, Signal Processing, Computer-Assisted, Holography methods, Image Processing, Computer-Assisted methods, Imaging, Three-Dimensional methods, Microscopy, Fluorescence methods

Abstract

Fluorescence holographic microscope (FINCHSCOPE) is a motionless fluorescence holographic imaging technique based on Fresnel incoherent correlation holography (FINCH) that shows promise in reconstructing three-dimensional fluorescence images of biological specimens with three holograms. We report a developing two-step phase-shifting method that reduces the required number of holograms from three to two. Using this method, we resolved microscopic fluorescent beads that were three-dimensionally distributed at different depths with two interferograms captured by a CCD camera. The method enables the FINCHSCOPE to work in conjunction with the frame-straddling technique and significantly enhance imaging speed.

Published

2014

36. Accurate single-shot quantitative phase imaging of biological specimens with telecentric digital holographic microscopy.

Author

Doblas A, Sánchez-Ortiga E, Martínez-Corral M, Saavedra G, and Garcia-Sucerquia J

Subjects

Animals, Drosophila melanogaster, Erythrocytes cytology, Head anatomy & histology, Holography methods, Image Processing, Computer-Assisted methods, Microscopy methods

Abstract

The advantages of using a telecentric imaging system in digital holographic microscopy (DHM) to study biological specimens are highlighted. To this end, the performances of nontelecentric DHM and telecentric DHM are evaluated from the quantitative phase imaging (QPI) point of view. The evaluated stability of the microscope allows single-shot QPI in DHM by using telecentric imaging systems. Quantitative phase maps of a section of the head of the drosophila melanogaster fly and of red blood cells are obtained via single-shot DHM with no numerical postprocessing. With these maps we show that the use of telecentric DHM provides larger field of view for a given magnification and permits more accurate QPI measurements with less number of computational operations.

Published

2014

37. Tomographic phase microscopy of living three-dimensional cell cultures.

Author

Kuś A, Dudek M, Kemper B, Kujawińska M, and Vollmer A

Subjects

Cell Line, Tumor, Equipment Design, Humans, Refractometry, Cell Culture Techniques methods, Holography methods, Tomography, Optical methods

Abstract

A successful application of self-interference digital holographic microscopy in combination with a sample-rotation-based tomography module for three-dimensional (3-D) label-free quantitative live cell imaging with subcellular resolution is demonstrated. By means of implementation of a hollow optical fiber as the sample cuvette, the observation of living cells in different 3-D matrices is enabled. The fiber delivers a stable and accurate rotation of a cell or cell cluster, providing quantitative phase data for tomographic reconstruction of the 3-D refractive index distribution with an isotropic spatial resolution. We demonstrate that it is possible to clearly distinguish and quantitatively analyze several cells grouped in a "3-D cluster" as well as subcellular organelles like the nucleoli and local internal refractive index changes.

Published

2014

38. Four-dimensional motility tracking of biological cells by digital holographic microscopy.

Author

Yu X, Hong J, Liu C, Cross M, Haynie DT, and Kim MK

Subjects

Cryptophyta cytology, Models, Biological, Cell Movement physiology, Cell Tracking methods, Holography methods

Abstract

Three-dimensional profiling and tracking by digital holography microscopy (DHM) provide label-free and quantitative analysis of the characteristics and dynamic processes of objects, since DHM can record real-time data for microscale objects and produce a single hologram containing all the information about their three-dimensional structures. Here, we have utilized DHM to visualize suspended microspheres and microfibers in three dimensions, and record the four-dimensional trajectories of free-swimming cells in the absence of mechanical focus adjustment. The displacement of microfibers due to interactions with cells in three spatial dimensions has been measured as a function of time at subsecond and micrometer levels in a direct and straightforward manner. It has thus been shown that DHM is a highly efficient and versatile means for quantitative tracking and analysis of cell motility.

Published

2014

39. Simultaneous multiplane imaging of human ovarian cancer by volume holographic imaging.

Author

Orsinger GV, Watson JM, Gordon M, Nymeyer AC, de Leon EE, Brownlee JW, Hatch KD, Chambers SK, Barton JK, Kostuk RK, and Romanowski M

Subjects

Adult, Aged, Fallopian Tubes anatomy & histology, Fallopian Tubes pathology, Female, Humans, Middle Aged, Ovary anatomy & histology, Ovary pathology, Young Adult, Histocytochemistry methods, Holography methods, Image Processing, Computer-Assisted methods, Optical Imaging methods, Ovarian Neoplasms pathology

Abstract

Ovarian cancer is the most deadly gynecologic cancer, a fact which is attributable to poor early detection and survival once the disease has reached advanced stages. Intraoperative laparoscopic volume holographic imaging has the potential to provide simultaneous visualization of surface and subsurface structures in ovarian tissues for improved assessment of developing ovarian cancer. In this ex vivo ovarian tissue study, we assembled a benchtop volume holographic imaging system (VHIS) to characterize the microarchitecture of 78 normal and 40 abnormal tissue specimens derived from ovarian, fallopian tube, uterine, and peritoneal tissues, collected from 26 patients aged 22 to 73 undergoing bilateral salpingo-oophorectomy, hysterectomy with bilateral salpingo-oophorectomy, or abdominal cytoreductive surgery. All tissues were successfully imaged with the VHIS in both reflectance- and fluorescence-modes revealing morphological features which can be used to distinguish between normal, benign abnormalities, and cancerous tissues. We present the development and successful application of VHIS for imaging human ovarian tissue. Comparison of VHIS images with corresponding histopathology allowed for qualitatively distinguishing microstructural features unique to the studied tissue type and disease state. These results motivate the development of a laparoscopic VHIS for evaluating the surface and subsurface morphological alterations in ovarian cancer pathogenesis.

Published

2014

40. Wavefront holoscopy: application of digital in-line holography for the inspection of engraved marks in progressive addition lenses.

Author

Perucho B and Micó V

Subjects

Algorithms, Automation, Calibration, Diagnostic Techniques, Ophthalmological, Equipment Design, Humans, Image Processing, Computer-Assisted, Imaging, Three-Dimensional, Lasers, Materials Testing, Normal Distribution, Reproducibility of Results, Eyeglasses, Holography methods, Lenses

Abstract

Progressive addition lenses (PALs) are engraved with permanent marks at standardized locations in order to guarantee correct centering and alignment throughout the manufacturing and mounting processes. Out of the production line, engraved marks provide useful information about the PAL as well as act as locator marks to re-ink again the removable marks. Even though those marks should be visible by simple visual inspection with the naked eye, engraving marks are often faint and weak, obscured by scratches, and partially occluded and difficult to recognize on tinted or antireflection-coated lenses. Here, we present an extremely simple optical device (named as wavefront holoscope) for visualization and characterization of permanent marks in PAL based on digital in-line holography. Essentially, a point source of coherent light illuminates the engraved mark placed just before a CCD camera that records a classical Gabor in-line hologram. The recorded hologram is then digitally processed to provide a set of high-contrast images of the engraved marks. Experimental results are presented showing the applicability of the proposed method as a new ophthalmic instrument for visualization and characterization of engraved marks in PALs.

Published

2014

41. Digital holographic microscopy for longitudinal volumetric imaging of growth and treatment response in three-dimensional tumor models.

Author

Li Y, Petrovic L, La J, Celli JP, and Yelleswarapu CS

Subjects

Antineoplastic Agents therapeutic use, Cell Line, Tumor, Humans, Organoplatinum Compounds pharmacology, Organoplatinum Compounds therapeutic use, Oxaliplatin, Antineoplastic Agents pharmacology, Holography methods, Imaging, Three-Dimensional methods, Microscopy methods, Models, Biological, Neoplasms drug therapy, Neoplasms pathology

Abstract

We report the use of digital holographic microscopy (DHM) as a viable microscopy approach for quantitative, nondestructive longitudinal imaging of in vitro three-dimensional (3-D) tumor models. Following established methods, we prepared 3-D cultures of pancreatic cancer cells in overlay geometry on extracellular matrix beds and obtained digital holograms at multiple time points throughout the duration of growth. The holograms were digitally processed and the unwrapped phase images were obtained to quantify the nodule thickness over time under normal growth and in cultures subject to chemotherapy treatment. In this manner, total nodule volumes are rapidly estimated and demonstrated here to show contrasting time-dependent changes during growth and in response to treatment. This work suggests the utility of DHM to quantify changes in 3-D structure over time and suggests the further development of this approach for time-lapse monitoring of 3-D morphological changes during growth and in response to treatment that would otherwise be impractical to visualize.

Published

2014

42. High-resolution three-dimensional imaging of red blood cells parasitized by Plasmodium falciparum and in situ hemozoin crystals using optical diffraction tomography.

Author

Kim K, Yoon H, Diez-Silva M, Dao M, Dasari RR, and Park Y

Subjects

Algorithms, Humans, Image Processing, Computer-Assisted methods, Malaria, Falciparum blood, Refractometry, Erythrocytes chemistry, Erythrocytes parasitology, Hemeproteins chemistry, Holography methods, Microscopy methods, Plasmodium falciparum chemistry, Tomography methods

Abstract

We present high-resolution optical tomographic images of human red blood cells (RBC) parasitized by malaria-inducing Plasmodium falciparum (Pf)-RBCs. Three-dimensional (3-D) refractive index (RI) tomograms are reconstructed by recourse to a diffraction algorithm from multiple two-dimensional holograms with various angles of illumination. These 3-D RI tomograms of Pf-RBCs show cellular and subcellular structures of host RBCs and invaded parasites in fine detail. Full asexual intraerythrocytic stages of parasite maturation (ring to trophozoite to schizont stages) are then systematically investigated using optical diffraction tomography algorithms. These analyses provide quantitative information on the structural and chemical characteristics of individual host Pf-RBCs, parasitophorous vacuole, and cytoplasm. The in situ structural evolution and chemical characteristics of subcellular hemozoin crystals are also elucidated.

Published

2014

43. Extraction of target specimens from bioholographic images using interactive graph cuts.

Author

Yi F, Moon I, and Lee YH

Subjects

Cytological Techniques, Diatoms cytology, Erythrocytes cytology, Helianthus cytology, Humans, Algorithms, Holography methods, Image Processing, Computer-Assisted methods

Abstract

It is necessary to extract target specimens from bioholographic images for high-level analysis such as object identification, recognition, and tracking with the advent of application of digital holographic microscopy to transparent or semi-transparent biological specimens. We present an interactive graph cuts approach to segment the needed target specimens in the reconstructed bioholographic images. This method combines both regional and boundary information and is robust to extract targets with weak boundaries. Moreover, this technique can achieve globally optimal results while minimizing an energy function. We provide a convenient user interface, which can easily differentiate the foreground/background for various types of holographic images, as well as a dynamically modified coefficient, which specifies the importance of the regional and boundary information. The extracted results from our scheme have been compared with those from an advanced level-set-based segmentation method using an unbiased comparison algorithm. Experimental results show that this interactive graph cut technique can not only extract different kinds of target specimens in bioholographic images, but also yield good results when there are multiple similar objects in the holographic image or when the object boundaries are very weak.

Published

2013

44. Role of Mandelbaum-like effect in the differentiation of hyperopes and myopes using a hologram.

Author

Nguyen N, Avudainayagam CS, and Avudainayagam KV

Subjects

Accommodation, Ocular, Adult, Female, Humans, Lighting methods, Male, Photic Stimulation methods, Reproducibility of Results, Sensitivity and Specificity, Eyeglasses, Holography methods, Hyperopia diagnosis, Hyperopia physiopathology, Hyperopia rehabilitation, Myopia diagnosis, Myopia physiopathology, Myopia rehabilitation, Refraction, Ocular, Vision Tests methods, Visual Acuity

Abstract

Recently, we tested the vision of spectacle corrected subjects using a special hologram (http://dx.doi.org/10.1364/BOE.3.001173). A subject viewing through this hologram sees the images of various numbers at different distances from the eye. Each of these images subtends an angle of 50' at the eye. Each image corresponds to a different amount of divergence or convergence at the eye. The limit of convergence (positive blur) with which a subject can recognize the numbers was measured. Hyperopes could recognize numbers with 0.9 D more of positive blur in comparison with myopes. This difference was not obtained with a standard test chart under white light illumination using positive lenses to provide the blur. The observed difference with the hologram is then attributed to the multivergence nature of the target in the hologram and/or the monochromaticity of the illumination used. Using a hologram of a logMAR chart at a single distance of infinity we have now found that the observed difference is induced by the multivergence target and is due to an effect that is similar to the Mandelbaum effect. We present the details of this experiment and compare the results obtained with our earlier experiment.

Published

2013

45. Interferometric study on birds' feathers.

Author

De la Torre-Ibarra MH and Santoyo FM

Subjects

Animals, Birds, Optical Phenomena, Wings, Animal anatomy & histology, Wings, Animal chemistry, Feathers chemistry, Holography methods, Image Processing, Computer-Assisted methods, Interferometry methods, Signal Processing, Computer-Assisted

Abstract

Optical techniques such as speckle pattern interferometry are well known in the nondestructive testing measurement community. They can be used, for instance, as a predictor of the mechanical behavior of a sample under study. However, in almost all circumstances, a mathematical model has to be applied in order to make sense of these measurements. This is a critical issue when an organic sample is studied, mainly due to its complex deformation response. A good example of this is observed in the birds' feathers. They have extraordinary mechanical and aerodynamic properties thanks to their stiffness and lightness. A couple of live birds are safely situated in front of an out-of-plane sensitive digital holographic interferometer (DHI), an optical system capable of recovering the optical phase in this type of nonrepeatable or unpredictable experiment. In order to recover the backscattering signal and its interferometric response, several images are recorded from different sections of the plumage. Displacement maps are obtained from what is, as far as is known, the first time that full field microdisplacement maps are presented over a hummingbird and a parakeet plumage.

Published

2013

46. Measurement of absolute cell volume, osmotic membrane water permeability, and refractive index of transmembrane water and solute flux by digital holographic microscopy.

Author

Boss D, Kühn J, Jourdain P, Depeursinge C, Magistretti PJ, and Marquet P

Subjects

Animals, CHO Cells, Cell Membrane Permeability, Cell Size, Cells, Cultured, Cricetinae, Cricetulus, Glutamic Acid pharmacokinetics, Glutamic Acid pharmacology, HEK293 Cells, Humans, Intracellular Space chemistry, Intracellular Space metabolism, Mice, Osmosis, Osmotic Pressure, Refractometry methods, Reproducibility of Results, Signal Processing, Computer-Assisted, Holography methods, Microscopy, Phase-Contrast methods, Water metabolism

Abstract

A dual-wavelength digital holographic microscope to measure absolute volume of living cells is proposed. The optical setup allows us to reconstruct two quantitative phase contrast images at two different wavelengths from a single hologram acquisition. When adding the absorbing dye fast green FCF as a dispersive agent to the extracellular medium, cellular thickness can be univocally determined in the full field of view. In addition to the absolute cell volume, the method can be applied to derive important biophysical parameters of living cells including osmotic membrane water permeability coefficient and the integral intracellular refractive index (RI). Further, the RI of transmembrane flux can be determined giving an indication about the nature of transported solutes. The proposed method is applied to cultured human embryonic kidney cells, Chinese hamster ovary cells, human red blood cells, mouse cortical astrocytes, and neurons.

Published

2013

47. Imaging the cellular response to transient shear stress using stroboscopic digital holography.

Author

Antkowiak M, Arita Y, Dholakia K, and Gunn-Moore F

Subjects

Animals, Biomechanical Phenomena physiology, CHO Cells, Cricetinae, Cricetulus, Cytoplasm physiology, Microbubbles, Nanoparticles, Polystyrenes, Stress, Mechanical, Cell Membrane Permeability physiology, Cell Shape physiology, Holography methods, Stroboscopy methods

Abstract

We use stroboscopic quantitative phase microscopy to study cell deformation and the response to cavitation bubbles and transient shear stress resulting from laser-induced breakdown of an optically trapped nanoparticle. A bi-directional transient displacement of cytoplasm is observed during expansion and collapse of the cavitation bubble. In some cases, cell deformation is only observable at the microsecond time scale without any permanent change in cell shape or optical thickness. On a time scale of seconds, the cellular response to shear stress and cytoplasm deformation typically leads to retraction of the cellular edge most exposed to the flow, rounding of the cell body and, in some cases, loss of cellular dry mass. These results give a new insight into the cellular response to cavitation induced shear stress and related plasma membrane permeabilization. This study also demonstrates that laser-induced breakdown of a nanoparticle offers localized cavitation, which interacts with a single cell but without causing cell lysis.

Published

2011

48. Lensless multispectral digital in-line holographic microscope.

Author

Ryle JP, McDonnell S, and Sheridan JT

Subjects

Algorithms, Animals, Cell Line, Color, Cricetinae, Equipment Design, Humans, Image Interpretation, Computer-Assisted, Mice, Microspheres, Optical Fibers, Signal Processing, Computer-Assisted, Holography instrumentation, Holography methods, Microscopy instrumentation, Microscopy methods, Models, Theoretical

Abstract

An compact multispectral digital in-line holographic microscope (DIHM) is developed that emulates Gabor's original holographic principle. Using sources of varying spatial coherence (laser, LED), holographic images of objects, including optical fiber, latex microspheres, and cancer cells, are successfully captured and numerically processed. Quantitative measurement of cell locations and percentage confluence are estimated, and pseudocolor images are also presented. Phase profiles of weakly scattering cells are obtained from the DIHM and are compared to those produced by a commercially available off-axis digital holographic microscope.

Published

2011

49. Toward soft-tissue elastography using digital holography to monitor surface acoustic waves.

Author

Li S, Mohan KD, Sanders WW, and Oldenburg AL

Subjects

Algorithms, Elastic Modulus, Elasticity Imaging Techniques instrumentation, Humans, Models, Biological, Phantoms, Imaging, Elasticity Imaging Techniques methods, Holography methods, Interferometry methods, Sound

Abstract

Measuring the elasticity distribution inside the human body is of great interest because elastic abnormalities can serve as indicators of several diseases. We present a method for mapping elasticity inside soft tissues by imaging surface acoustic waves (SAWs) with digital holographic interferometry. With this method, we show that SAWs are consistent with Rayleigh waves, with velocities proportional to the square root of the elastic modulus greater than 2-40 kPa in homogeneous tissue phantoms. In two-layer phantoms, the SAW velocity transitions approximately from that of the lower layer to that of the upper layer as frequency is increased in agreement with the theoretical relationship between SAW dispersion and the depth-dependent stiffness profile. We also observed deformation in the propagation direction of SAWs above a stiff inclusion placed 8 mm below the surface. These findings demonstrate the potential for quantitative digital holography-based elastography of soft tissues as a noninvasive method for disease detection.

Published

2011

50. Beyond the lateral resolution limit by phase imaging.

Author

Cotte Y, Toy MF, and Depeursinge C

Subjects

Holography methods, Holography statistics & numerical data, Microscopy, Electron, Scanning methods, Microscopy, Electron, Scanning statistics & numerical data, Microscopy, Interference statistics & numerical data, Microscopy, Phase-Contrast methods, Microscopy, Phase-Contrast statistics & numerical data, Models, Theoretical, Nanostructures ultrastructure, Optical Phenomena, Scattering, Radiation, Signal-To-Noise Ratio, Microscopy, Interference methods

Abstract

We present a theory to extend the classical Abbe resolution limit by introducing a spatially varying phase into the illumination beam of a phase imaging system. It allows measuring lateral and axial distance differences between point sources to a higher accuracy than intensity imaging alone. Various proposals for experimental realization are debated. Concretely, the phase of point scatterers' interference is experimentally visualized by high numerical aperture (NA = 0.93) digital holographic microscopy combined with angular scanning. Proof-of-principle measurements are presented by using sub-wavelength nanometric holes on an opaque metallic film. In this manner, Rayleighs classical two-point resolution condition can be rebuilt. With different illumination phases, enhanced bandpass information content is demonstrated, and its spatial resolution is theoretically shown to be potentially signal-to-noise ratio limited.

Published

2011