Imaging single chiral nanoparticles in turbid media using circular-polarization optical coherence microscopy

Zhang, Peng-Fei; Mehta, Kalpesh; Rehman, Shakil; Chen, Nanguang

doi:10.1038/srep04979

Cited by 10 publications

(11 citation statements)

References 27 publications

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“…OCT is an interferometric technique providing high-resolution cross-sectional tissue images by detection of the intensity of a low-coherence light reflected from tissue layers or other inhomogeneities. 2,5,274 To study complex anisotropic tissues possessing microscopic fibrous structures, including collagen fibers and nerve fibers, a conventional OCT was improved by enabling measurements of signal polarization characteristics, which is the PS-OCT. 2,5,9,15,21,22,61,62,66,67,103,129,132,163,202,[256][257][258][259][260]268 In-depth measurements of Stokes parameters allow for determination of tissue birefringence (phase retardation), dichroism (diattenuation), and optic-axis orientation. Advanced PS-OCT systems give the possibility for tissue imaging by measurements of a full Jones matrix 103,202,239,241,242 or Mueller matrix 61,62,67,202,239 for each pixel, as well as representing results of imaging in the form of the Poincaré sphere.…”

Section: Polarization-sensitive Optical Coherence Tomographymentioning

confidence: 99%

“…A novel approach toward significant enhancement of image contrast of OCT microscopy was recently demonstrated. 268 It is based on the combination of a circular-polarization OCT system with 3-D chiral nanostructures as contrast agents. By detecting the circular intensity differential depolarization, high-quality images of single chiral nanoparticles underneath a 1-mmthick tissue-mimicking phantom were successfully acquired.…”

Section: Nanoparticle Enhancement Of Contrast Of Polarized Light Micrmentioning

confidence: 99%

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Polarized light interaction with tissues

2016

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This tutorial-review introduces the fundamentals of polarized light interaction with biological tissues and presents some of the recent key polarization optical methods that have made possible the quantitative studies essential for biomedical diagnostics. Tissue structures and the corresponding models showing linear and circular birefringence, dichroism, and chirality are analyzed. As the basis for a quantitative description of the interaction of polarized light with tissues, the theory of polarization transfer in a random medium is used. This theory employs the modified transfer equation for Stokes parameters to predict the polarization properties of single- and multiple-scattered optical fields. The near-order of scatterers in tissues is accounted for to provide an adequate description of tissue polarization properties. Biomedical diagnostic techniques based on polarized light detection, including polarization imaging and spectroscopy, amplitude and intensity light scattering matrix measurements, and polarization-sensitive optical coherence tomography are described. Examples of biomedical applications of these techniques for early diagnostics of cataracts, detection of precancer, and prediction of skin disease are presented. The substantial reduction of light scattering multiplicity at tissue optical clearing that leads to a lesser influence of scattering on the measured intrinsic polarization properties of the tissue and allows for more precise quantification of these properties is demonstrated.

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Section: Polarization-sensitive Optical Coherence Tomographymentioning

confidence: 99%

Section: Nanoparticle Enhancement Of Contrast Of Polarized Light Micrmentioning

confidence: 99%

Polarized light interaction with tissues

2016

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“…65,66 These tissues are turbid compared with the 24 hpf embryo, and we could only find one report of OCM imaging on 24 hpf zebrafish 67 in which the signal seemed comparable with our data, relatively weak, presumably due to the transparency of the embryo. There have been efforts to use OCM for imaging with molecular contrast such as detecting backscattered light from gold nanoparticles conjugate to antibodies for immunodetection 68,69 and using spectral domain detection to look for absorption signatures of specific molecules such as hemoglobin. There have been efforts to use OCM for imaging with molecular contrast such as detecting backscattered light from gold nanoparticles conjugate to antibodies for immunodetection 68,69 and using spectral domain detection to look for absorption signatures of specific molecules such as hemoglobin.…”

Section: Imaging Domains Of Gene Expression With Two-photon Fluorescementioning

confidence: 99%

Combined lineage mapping and gene expression profiling of embryonic brain patterning using ultrashort pulse microscopy and image registration

et al. 2014

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During embryogenesis, presumptive brain compartments are patterned by dynamic networks of gene expression. The spatiotemporal dynamics of these networks, however, have not been characterized with sufficient resolution for us to understand the regulatory logic resulting in morphogenetic cellular behaviors that give the brain its shape. We have developed a new, integrated approach using ultrashort pulse microscopy [a high-resolution, two-photon fluorescence (2PF)-optical coherence microscopy (OCM) platform using 10-fs pulses] and image registration to study brain patterning and morphogenesis in zebrafish embryos. As a demonstration, we used time-lapse 2PF to capture midbrain-hindbrain boundary morphogenesis and a wnt1 lineage map from embryos during brain segmentation. We then performed in situ hybridization to deposit NBT/BCIP, where wnt1 remained actively expressed, and reimaged the embryos with combined 2PF-OCM. When we merged these datasets using morphological landmark registration, we found that the mechanism of boundary formation differs along the dorsoventral axis. Dorsally, boundary sharpening is dominated by changes in gene expression, while ventrally, sharpening may be accomplished by lineage sorting. We conclude that the integrated visualization of lineage reporter and gene expression domains simultaneously with brain morphology will be useful for understanding how changes in gene expression give rise to proper brain compartmentalization and structure.

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“…Sensitivity and accuracy of polarization measurements have to be guaranteed in the highly scattering medium. Previous reports on PS-OCM succeeded to visualize muscle structures [12] and chiral nanoparticles in scattering medium [13]. Quantitative analysis of birefringence and the axis of anisotropy have yet to be investigated.…”

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confidence: 99%

Polarization sensitive optical coherence microscopy for brain imaging

et al. 2016

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Optical coherence tomography (OCT) and optical coherence microscopy (OCM) have demonstrated the ability to investigate cyto- and myelo-architecture in the brain. Polarization-sensitive OCT provides sensitivity to additional contrast mechanisms, specifically the birefringence of myelination, and therefore is advantageous for investigating white matter fiber tracts. In this study, we developed a polarization-sensitive optical coherence microscope (PS-OCM) with 3.5 μm axial and 1.3 μm transverse resolution to investigate fiber organization and orientation at a finer scale than previously demonstrated with PS-OCT. In a fully reconstructed mouse brain section, we showed that at the focal depths of 20 – 70 μm, the PS-OCM reliably identifies the neuronal fibers and quantifies the in-plane orientation.

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Imaging single chiral nanoparticles in turbid media using circular-polarization optical coherence microscopy

Cited by 10 publications

References 27 publications

Polarized light interaction with tissues

Polarized light interaction with tissues

Combined lineage mapping and gene expression profiling of embryonic brain patterning using ultrashort pulse microscopy and image registration

Polarization sensitive optical coherence microscopy for brain imaging

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