Your search keyword '"Adie SG"' showing total 53 results

1. Abstract P2-03-11: In situ imaging of the tumor cavity during breast lumpectomy using optical coherence tomography

Author

Boppart, SA, primary, Nolan, RM, additional, Erickson-Bhatt, SJ, additional, Shemonski, ND, additional, Adie, SG, additional, Putney, J, additional, Darga, D, additional, McCormick, DT, additional, Cittadine, A, additional, Marjanovic, M, additional, Zysk, AM, additional, Chaney, EJ, additional, Monroy, GL, additional, South, FA, additional, Carney, PS, additional, Cradock, KA, additional, Liu, ZG, additional, and Ray, PS, additional

Published

2013

2. Abstract P1-01-23: Intraoperative optical coherence tomography for the assessment of metastatic disease in human lymph nodes

Author

Marjanovic, M, primary, Adie, SG, additional, Nolan, RM, additional, Chaney, EJ, additional, Shemonski, ND, additional, South, FA, additional, Erickson-Bhatt, SJ, additional, Shelton, RL, additional, Bower, AJ, additional, Simpson, DG, additional, Ray, PS, additional, Cradock, KA, additional, Brockenbrough, J, additional, Liu, G, additional, and Boppart, SA, additional

Published

2013

3. Abstract OT2-1-04: Intraoperative assessment of tumor margins with a new optical imaging technology: A multi-center, randomized, blinded clinical trial

Author

Jacobs, LK, primary, Carney, PS, additional, Cittadine, AJ, additional, McCormick, DT, additional, Somera, AL, additional, Darga, DA, additional, Putney, JL, additional, Adie, SG, additional, Ray, P, additional, Cradock, KA, additional, Tafra, L, additional, Gabrielson, EW, additional, and Boppart, SA, additional

Published

2012

4. Recent advances in optical elastography and emerging opportunities in the basic sciences and translational medicine [Invited].

Author

Leartprapun N and Adie SG

Abstract

Optical elastography offers a rich body of imaging capabilities that can serve as a bridge between organ-level medical elastography and single-molecule biophysics. We review the methodologies and recent developments in optical coherence elastography, Brillouin microscopy, optical microrheology, and photoacoustic elastography. With an outlook toward maximizing the basic science and translational clinical impact of optical elastography technologies, we discuss potential ways that these techniques can integrate not only with each other, but also with supporting technologies and capabilities in other biomedical fields. By embracing cross-modality and cross-disciplinary interactions with these parallel fields, optical elastography can greatly increase its potential to drive new discoveries in the biomedical sciences as well as the development of novel biomechanics-based clinical diagnostics and therapeutics., Competing Interests: The authors declare that there are no conflicts of interest related to this article., (© 2022 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.)

Published

2022

5. Light-sheet photonic force optical coherence elastography for high-throughput quantitative 3D micromechanical imaging.

Author

Lin Y, Leartprapun N, Luo JC, and Adie SG

Subjects

Biomechanical Phenomena, Extracellular Matrix, Imaging, Three-Dimensional, Viscosity, Elasticity Imaging Techniques

Abstract

Quantitative characterisation of micro-scale mechanical properties of the extracellular matrix (ECM) and dynamic cell-ECM interactions can significantly enhance fundamental discoveries and their translational potential in the rapidly growing field of mechanobiology. However, quantitative 3D imaging of ECM mechanics with cellular-scale resolution and dynamic monitoring of cell-mediated changes to pericellular viscoelasticity remain a challenge for existing mechanical characterisation methods. Here, we present light-sheet photonic force optical coherence elastography (LS-pfOCE) to address this need by leveraging a light-sheet for parallelised, non-invasive, and localised mechanical loading. We demonstrate the capabilities of LS-pfOCE by imaging the micromechanical heterogeneity of fibrous collagen matrices and perform live-cell imaging of cell-mediated ECM micromechanical dynamics. By providing access to 4D spatiotemporal variations in the micromechanical properties of 3D biopolymer constructs and engineered cellular systems, LS-pfOCE has the potential to drive new discoveries in mechanobiology and contribute to the development of novel biomechanics-based clinical diagnostics and therapies., (© 2022. The Author(s).)

Published

2022

6. Resolution-enhanced OCT and expanded framework of information capacity and resolution in coherent imaging.

Author

Leartprapun N and Adie SG

Subjects

Animals, Brain diagnostic imaging, Mice, Inbred C57BL, Phantoms, Imaging, Mice, Image Interpretation, Computer-Assisted, Signal-To-Noise Ratio, Tomography, Optical Coherence

Abstract

Spatial resolution in conventional optical microscopy has traditionally been treated as a fixed parameter of the optical system. Here, we present an approach to enhance transverse resolution in beam-scanned optical coherence tomography (OCT) beyond its aberration-free resolution limit, without any modification to the optical system. Based on the theorem of invariance of information capacity, resolution-enhanced (RE)-OCT navigates the exchange of information between resolution and signal-to-noise ratio (SNR) by exploiting efficient noise suppression via coherent averaging and a simple computational bandwidth expansion procedure. We demonstrate a resolution enhancement of 1.5 × relative to the aberration-free limit while maintaining comparable SNR in silicone phantom. We show that RE-OCT can significantly enhance the visualization of fine microstructural features in collagen gel and ex vivo mouse brain. Beyond RE-OCT, our analysis in the spatial-frequency domain leads to an expanded framework of information capacity and resolution in coherent imaging that contributes new implications to the theory of coherent imaging. RE-OCT can be readily implemented on most OCT systems worldwide, immediately unlocking information that is beyond their current imaging capabilities, and so has the potential for widespread impact in the numerous areas in which OCT is utilized, including the basic sciences and translational medicine., (© 2021. The Author(s).)

Published

2021

7. Closed-loop wavefront sensing and correction in the mouse brain with computed optical coherence microscopy.

Author

Liu S, Xia F, Yang X, Wu M, Bizimana LA, Xu C, and Adie SG

Abstract

Optical coherence microscopy (OCM) uses interferometric detection to capture the complex optical field with high sensitivity, which enables computational wavefront retrieval using back-scattered light from the sample. Compared to a conventional wavefront sensor, aberration sensing with OCM via computational adaptive optics (CAO) leverages coherence and confocal gating to obtain signals from the focus with less cross-talk from other depths or transverse locations within the field-of-view. Here, we present an investigation of the performance of CAO-based aberration sensing in simulation, bead phantoms, and ex vivo mouse brain tissue. We demonstrate that, due to the influence of the double-pass confocal OCM imaging geometry on the shape of computed pupil functions, computational sensing of high-order aberrations can suffer from signal attenuation in certain spatial-frequency bands and shape similarity with lower order counterparts. However, by sensing and correcting only low-order aberrations (astigmatism, coma, and trefoil), we still successfully corrected tissue-induced aberrations, leading to 3× increase in OCM signal intensity at a depth of ∼0.9 mm in a freshly dissected ex vivo mouse brain., Competing Interests: The authors declare that there are no conflicts of interest related to this article., (© 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement.)

Published

2021

8. Computational 4D-OCM for label-free imaging of collective cell invasion and force-mediated deformations in collagen.

Author

Mulligan JA, Ling L, Leartprapun N, Fischbach C, and Adie SG

Subjects

Adipose Tissue cytology, Animals, Biomechanical Phenomena, Cell Adhesion, Cell Line, Tumor, Cell Movement, Computer Simulation, Extracellular Matrix metabolism, Extracellular Matrix pathology, Humans, Mice, Neoplasm Invasiveness, Primary Cell Culture, Proteolysis, Spheroids, Cellular, Stromal Cells, Time-Lapse Imaging methods, Collagen metabolism, Intravital Microscopy methods, Models, Biological, Neoplasms pathology, Optical Imaging methods

Abstract

Traction force microscopy (TFM) is an important family of techniques used to measure and study the role of cellular traction forces (CTFs) associated with many biological processes. However, current standard TFM methods rely on imaging techniques that do not provide the experimental capabilities necessary to study CTFs within 3D collective and dynamic systems embedded within optically scattering media. Traction force optical coherence microscopy (TF-OCM) was developed to address these needs, but has only been demonstrated for the study of isolated cells embedded within optically clear media. Here, we present computational 4D-OCM methods that enable the study of dynamic invasion behavior of large tumor spheroids embedded in collagen. Our multi-day, time-lapse imaging data provided detailed visualizations of evolving spheroid morphology, collagen degradation, and collagen deformation, all using label-free scattering contrast. These capabilities, which provided insights into how stromal cells affect cancer progression, significantly expand access to critical data about biophysical interactions of cells with their environment, and lay the foundation for future efforts toward volumetric, time-lapse reconstructions of collective CTFs with TF-OCM.

Published

2021

9. Obesity-associated Adipose Stromal Cells Promote Breast Cancer Invasion Through Direct Cell Contact and ECM Remodeling.

Author

Ling L, Mulligan JA, Ouyang Y, Shimpi AA, Williams RM, Beeghly GF, Hopkins BD, Spector JA, Adie SG, and Fischbach C

Abstract

Obesity increases the risk and worsens the prognosis for breast cancer due, in part, to altered adipose stromal cell (ASC) behavior. Whether ASCs from obese individuals increase migration of breast cancer cells relative to their lean counterparts, however, remains unclear. To test this connection, multicellular spheroids composed of MCF10A-derived tumor cell lines of varying malignant potential and lean or obese ASCs were embedded into collagen scaffolds mimicking the elastic moduli of interstitial breast adipose tissue. Confocal image analysis suggests that tumor cells alone migrate insignificantly under these conditions. However, direct cell-cell contact with either lean or obese ASCs enables them to migrate collectively, whereby obese ASCs activate tumor cell migration more effectively than their lean counterparts. Time-resolved optical coherence tomography (OCT) imaging suggests that obese ASCs facilitate tumor cell migration by mediating contraction of local collagen fibers. Matrix metalloproteinase (MMP)-dependent proteolytic activity significantly contributes to ASC-mediated tumor cell invasion and collagen deformation. However, ASC contractility is also important, as co-inhibition of both MMPs and contractility is necessary to completely abrogate ASC-mediated tumor cell migration. These findings imply that obesity-mediated changes of ASC phenotype may impact tumor cell migration and invasion with potential implications for breast cancer malignancy in obese patients.

Published

2020

10. Computed optical coherence microscopy of mouse brain ex vivo.

Author

Wu M, Small DM, Nishimura N, and Adie SG

Subjects

Algorithms, Animals, Computer Simulation, Fourier Analysis, Green Fluorescent Proteins metabolism, Heterozygote, Interferometry, Mice, Normal Distribution, Optics and Photonics, Signal-To-Noise Ratio, Brain diagnostic imaging, Image Processing, Computer-Assisted, Microscopy, Tomography, Optical Coherence

Abstract

The compromise between lateral resolution and usable imaging depth range is a bottleneck for optical coherence tomography (OCT). Existing solutions for optical coherence microscopy (OCM) suffer from either large data size and long acquisition time or a nonideal point spread function. We present volumetric OCM of mouse brain ex vivo with a large depth coverage by leveraging computational adaptive optics (CAO) to significantly reduce the number of OCM volumes that need to be acquired with a Gaussian beam focused at different depths. We demonstrate volumetric reconstruction of ex-vivo mouse brain with lateral resolution of 2.2  μm, axial resolution of 4.7  μm, and depth range of ∼1.2  mm optical path length, using only 11 OCT data volumes acquired on a spectral-domain OCM system. Compared to focus scanning with step size equal to the Rayleigh length of the beam, this is a factor of 4 fewer datasets required for volumetric imaging. Coregistered two-photon microscopy confirmed that CAO-OCM reconstructions can visualize various tissue microstructures in the brain. Our results also highlight the limitations of CAO in highly scattering media, particularly when attempting to reconstruct far from the focal plane or when imaging deep within the sample.

Published

2019

11. Spatial localization of mechanical excitation affects spatial resolution, contrast, and contrast-to-noise ratio in acoustic radiation force optical coherence elastography.

Author

Leartprapun N, Iyer RR, Mackey CD, and Adie SG

Abstract

The notion that a spatially confined mechanical excitation would produce an elastogram with high spatial resolution has motivated the development of various elastography techniques with localized mechanical excitation. However, a quantitative investigation of the effects of spatial localization of mechanical excitation on the spatial resolution of elastograms is still lacking in optical coherence elastography (OCE). Here, we experimentally investigated the effect of spatial localization of acoustic radiation force (ARF) excitation on spatial resolution, contrast, and contrast-to-noise ratio (CNR) of dynamic uniaxial strain elastograms in dynamic ARF-OCE, based on a framework for analyzing the factors that influence the quality of the elastogram at different stages of the elastography workflow. Our results show that localized ARF excitation with a smaller acoustic focal spot size produced a strain elastogram with superior spatial resolution, contrast, and CNR. Our results also suggest that the spatial extent spanned by the displacement response in the sample may connect between the spatial localization of the mechanical excitation and the resulting elastogram quality. The elastography framework and experimental approach presented here may provide a basis for the quantitative analysis of elastogram quality in OCE that can be adapted and applied to different OCE systems and applications., Competing Interests: The authors declare no conflicts of interest., (© 2019 Optical Society of America under the terms of the OSA Open Access Publishing Agreement.)

Published

2019

12. Spectroscopic photonic force optical coherence elastography.

Author

Lin Y, Leartprapun N, and Adie SG

Abstract

We demonstrate spectroscopic photonic force optical coherence elastography (PF-OCE). Oscillations of microparticles embedded in viscoelastic hydrogels were induced by harmonically modulated optical radiation pressure and measured by phase-sensitive spectral-domain optical coherence tomography. PF-OCE can detect microparticle displacements with pico- to nano-meter sensitivity and millimeter-scale volumetric coverage. With spectroscopic PF-OCE, we quantified viscoelasticity over a broad frequency range from 1 Hz to 7 kHz, revealing rich microstructural dynamics of polymer networks across multiple microrheological regimes. Reconstructed frequency-dependent loss moduli of polyacrylamide hydrogels were observed to follow a general power scaling law G '' ∼ω 0.75 , consistent with that of semiflexible polymer networks. Spectroscopic PF-OCE provides an all-optical approach to microrheological studies with high sensitivity and high spatiotemporal resolution, and could be especially beneficial for time-lapse and volumetric mechanical characterization of viscoelastic materials.

Published

2019

13. Microrheological quantification of viscoelastic properties with photonic force optical coherence elastography.

Author

Leartprapun N, Lin Y, and Adie SG

Abstract

Photonic force optical coherence elastography (PF-OCE) is a new approach for volumetric characterization of microscopic mechanical properties of three-dimensional viscoelastic medium. It is based on measurements of the complex mechanical response of embedded micro-beads to harmonically modulated radiation-pressure force from a weakly-focused beam. Here, we utilize the Generalized Stokes-Einstein relation to reconstruct local complex shear modulus in polyacrylamide gels by combining PF-OCE measurements of bead mechanical responses and experimentally measured depth-resolved radiation-pressure force profile of our forcing beam. Data exclusion criteria for quantitative PF-OCE based on three noise-related parameters were identified from the analysis of measurement noise at key processing steps. Shear storage modulus measured by quantitative PF-OCE was found to be in good agreement with standard shear rheometry, whereas shear loss modulus was in agreement with previously published atomic force microscopy results. The analysis and results presented here may serve to inform practical, application-specific implementations of PF-OCE, and establish the technique as a viable tool for quantitative mechanical microscopy.

Published

2019

14. Quantitative reconstruction of time-varying 3D cell forces with traction force optical coherence microscopy.

Author

Mulligan JA, Feng X, and Adie SG

Subjects

Algorithms, Animals, Cell Adhesion genetics, Computer Simulation, Imaging, Three-Dimensional methods, Mice, Microscopy, Confocal methods, NIH 3T3 Cells, Fibroblasts ultrastructure, Mechanical Phenomena, Microscopy, Atomic Force methods, Traction methods

Abstract

Cellular traction forces (CTFs) play an integral role in both physiological processes and disease, and are a topic of interest in mechanobiology. Traction force microscopy (TFM) is a family of methods used to quantify CTFs in a variety of settings. State-of-the-art 3D TFM methods typically rely on confocal fluorescence microscopy, which can impose limitations on acquisition speed, volumetric coverage, and temporal sampling or coverage. In this report, we present the first quantitative implementation of a new TFM technique: traction force optical coherence microscopy (TF-OCM). TF-OCM leverages the capabilities of optical coherence microscopy and computational adaptive optics (CAO) to enable the quantitative reconstruction of 3D CTFs in scattering media with minute-scale temporal sampling. We applied TF-OCM to quantify CTFs exerted by isolated NIH-3T3 fibroblasts embedded in Matrigel, with five-minute temporal sampling, using images spanning a 500 × 500 × 500 μm 3 field-of-view. Due to the reliance of TF-OCM on computational imaging methods, we have provided extensive discussion of the equations, assumptions, and failure modes of these methods. By providing high-throughput, label-free, volumetric imaging in scattering media, TF-OCM is well-suited to the study of 3D CTF dynamics, and may prove advantageous for the study of large cell collectives, such as the spheroid models prevalent in mechanobiology.

Published

2019

15. Aberration-diverse optical coherence tomography for suppression of multiple scattering and speckle.

Author

Liu S, Lamont MRE, Mulligan JA, and Adie SG

Abstract

Multiple scattering is a major barrier that limits the optical imaging depth in scattering media. In order to alleviate this effect, we demonstrate aberration-diverse optical coherence tomography (AD-OCT), which exploits the phase correlation between the deterministic signals from single-scattered photons to suppress the random background caused by multiple scattering and speckle. AD-OCT illuminates the sample volume with diverse aberrated point spread functions, and computationally removes these intentionally applied aberrations. After accumulating 12 astigmatism-diverse OCT volumes, we show a 10 dB enhancement in signal-to-background ratio via a coherent average of reconstructed signals from a USAF target located 7.2 scattering mean free paths below a thick scattering layer, and a 3× speckle contrast reduction from an incoherent average of reconstructed signals inside the scattering layer. This AD-OCT method, when implemented using astigmatic illumination, is a promising approach for ultra-deep volumetric optical coherence microscopy., Competing Interests: The authors declare a conflict of interest. S.L., M.R.E.L., and S.G.A. are listed as inventors on a patent application related to the work presented in this manuscript.

Published

2018

16. Volumetric optical coherence microscopy with a high space-bandwidth- time product enabled by hybrid adaptive optics.

Author

Liu S, Mulligan JA, and Adie SG

Abstract

Optical coherence microscopy (OCM) is a promising modality for high resolution imaging, but has limited ability to capture large-scale volumetric information about dynamic biological processes with cellular resolution. To enhance the throughput of OCM, we implemented a hybrid adaptive optics (hyAO) approach that combines computational adaptive optics with an intentionally aberrated imaging beam generated via hardware adaptive optics. Using hyAO, we demonstrate the depth-equalized illumination and collection ability of an astigmatic beam compared to a Gaussian beam for cellular-resolution imaging. With this advantage, we achieved volumetric OCM with a higher space-bandwidth- time product compared to Gaussian-beam acquisition that employed focus-scanning across depth. HyAO was also used to perform volumetric time-lapse OCM imaging of cellular dynamics over a 1mm × 1mm × 1mm field-of-view with 2 μm isotropic spatial resolution and 3-minute temporal resolution. As hyAO is compatible with both spectral-domain and swept-source beam-scanning OCM systems, significant further improvements in absolute volumetric throughput are possible by use of ultrahigh-speed swept sources., Competing Interests: The authors declare that there are no conflicts of interest related to this article.

Published

2018

17. Photonic force optical coherence elastography for three-dimensional mechanical microscopy.

Author

Leartprapun N, Iyer RR, Untracht GR, Mulligan JA, and Adie SG

Subjects

Biomechanical Phenomena, Hydrogels, Photons, Rheology methods, Elasticity Imaging Techniques methods, Imaging, Three-Dimensional methods, Microscopy methods, Optical Tweezers, Tomography, Optical Coherence methods

Abstract

Optical tweezers are an invaluable tool for non-contact trapping and micro-manipulation, but their ability to facilitate high-throughput volumetric microrheology of biological samples for mechanobiology research is limited by the precise alignment associated with the excitation and detection of individual bead oscillations. In contrast, radiation pressure from a low-numerical aperture optical beam can apply transversely localized force over an extended depth range. Here we present photonic force optical coherence elastography (PF-OCE), leveraging phase-sensitive interferometric detection to track sub-nanometer oscillations of beads, embedded in viscoelastic hydrogels, induced by modulated radiation pressure. Since the displacements caused by ultra-low radiation-pressure force are typically obscured by absorption-mediated thermal effects, mechanical responses of the beads were isolated after independent measurement and decoupling of the photothermal response of the hydrogels. Volumetric imaging of bead mechanical responses in hydrogels with different agarose concentrations by PF-OCE was consistent with bulk mechanical characterization of the hydrogels by shear rheometry.

Published

2018

18. Depth-resolved measurement of optical radiation-pressure forces with optical coherence tomography.

Author

Leartprapun N, Iyer RR, and Adie SG

Abstract

A weakly focused laser beam can exert sufficient radiation pressure to manipulate microscopic particles over a large depth range. However, depth-resolved continuous measurement of radiation-pressure force profiles over an extended range about the focal plane has not been demonstrated despite decades of research on optical manipulation. Here, we present a method for continuous measurement of axial radiation-pressure forces from a weakly focused beam on polystyrene micro-beads suspended in viscous fluids over a depth range of 400 μm, based on real-time monitoring of particle dynamics using optical coherence tomography (OCT). Measurements of radiation-pressure forces as a function of beam power, wavelength, bead size, and refractive index are consistent with theoretical trends. However, our continuous measurements also reveal localized depth-dependent features in the radiation-pressure force profiles that deviate from theoretical predictions based on an aberration-free Gaussian beam. The combination of long-range radiation pressure and OCT offers a new mode of quantitative optical manipulation and detection with extended spatial coverage. This may find applications in the characterization of optical tractor beams, or volumetric optical manipulation and interrogation of beads in viscoelastic media.

Published

2018

19. Traction Force Microscopy for Noninvasive Imaging of Cell Forces.

Author

Mulligan JA, Bordeleau F, Reinhart-King CA, and Adie SG

Subjects

Biomechanical Phenomena, Humans, Models, Biological, Extracellular Matrix, Microscopy, Atomic Force methods

Abstract

The forces exerted by cells on their surroundings play an integral role in both physiological processes and disease progression. Traction force microscopy is a noninvasive technique that enables the in vitro imaging and quantification of cell forces. Utilizing expertise from a variety of disciplines, recent developments in traction force microscopy are enhancing the study of cell forces in physiologically relevant model systems, and hold promise for further advancing knowledge in mechanobiology. In this chapter, we discuss the methods, capabilities, and limitations of modern approaches for traction force microscopy, and highlight ongoing efforts and challenges underlying future innovations.

Published

2018

20. Measurement of dynamic cell-induced 3D displacement fields in vitro for traction force optical coherence microscopy.

Author

Mulligan JA, Bordeleau F, Reinhart-King CA, and Adie SG

Abstract

Traction force microscopy (TFM) is a method used to study the forces exerted by cells as they sense and interact with their environment. Cell forces play a role in processes that take place over a wide range of spatiotemporal scales, and so it is desirable that TFM makes use of imaging modalities that can effectively capture the dynamics associated with these processes. To date, confocal microscopy has been the imaging modality of choice to perform TFM in 3D settings, although multiple factors limit its spatiotemporal coverage. We propose traction force optical coherence microscopy (TF-OCM) as a novel technique that may offer enhanced spatial coverage and temporal sampling compared to current methods used for volumetric TFM studies. Reconstructed volumetric OCM data sets were used to compute time-lapse extracellular matrix deformations resulting from cell forces in 3D culture. These matrix deformations revealed clear differences that can be attributed to the dynamic forces exerted by normal versus contractility-inhibited NIH-3T3 fibroblasts embedded within 3D Matrigel matrices. Our results are the first step toward the realization of 3D TF-OCM, and they highlight the potential use of OCM as a platform for advancing cell mechanics research.

Published

2017

21. Intraoperative optical coherence tomography for assessing human lymph nodes for metastatic cancer.

Author

Nolan RM, Adie SG, Marjanovic M, Chaney EJ, South FA, Monroy GL, Shemonski ND, Erickson-Bhatt SJ, Shelton RL, Bower AJ, Simpson DG, Cradock KA, Liu ZG, Ray PS, and Boppart SA

Subjects

Adult, Aged, Aged, 80 and over, Double-Blind Method, Female, Humans, Intraoperative Period, Lymph Nodes, Middle Aged, Observer Variation, Sensitivity and Specificity, Breast Neoplasms pathology, Breast Neoplasms surgery, Lymphatic Metastasis diagnosis, Tomography, Optical Coherence methods

Abstract

Background: Evaluation of lymph node (LN) status is an important factor for detecting metastasis and thereby staging breast cancer. Currently utilized clinical techniques involve the surgical disruption and resection of lymphatic structure, whether nodes or axillary contents, for histological examination. While reasonably effective at detection of macrometastasis, the majority of the resected lymph nodes are histologically negative. Improvements need to be made to better detect micrometastasis, minimize or eliminate lymphatic disruption complications, and provide immediate and accurate intraoperative feedback for in vivo cancer staging to better guide surgery., Methods: We evaluated the use of optical coherence tomography (OCT), a high-resolution, real-time, label-free imaging modality for the intraoperative assessment of human LNs for metastatic disease in patients with breast cancer. We assessed the sensitivity and specificity of double-blinded trained readers who analyzed intraoperative OCT LN images for presence of metastatic disease, using co-registered post-operative histopathology as the gold standard., Results: Our results suggest that intraoperative OCT examination of LNs is an appropriate real-time, label-free, non-destructive alternative to frozen-section analysis, potentially offering faster interpretation and results to empower superior intraoperative decision-making., Conclusions: Intraoperative OCT has strong potential to supplement current post-operative histopathology with real-time in situ assessment of LNs to preserve both non-cancerous nodes and their lymphatic vessels, and thus reduce the associated risks and complications from surgical disruption of lymphoid structures following biopsy.

Published

2016

22. Computational Aberration Correction for Human Retinal Imaging.

Author

Shemonski ND, South FA, Liu YZ, Adie SG, Carney PS, and Boppart SA

Published

2015

23. Real-time Imaging of the Resection Bed Using a Handheld Probe to Reduce Incidence of Microscopic Positive Margins in Cancer Surgery.

Author

Erickson-Bhatt SJ, Nolan RM, Shemonski ND, Adie SG, Putney J, Darga D, McCormick DT, Cittadine AJ, Zysk AM, Marjanovic M, Chaney EJ, Monroy GL, South FA, Cradock KA, Liu ZG, Sundaram M, Ray PS, and Boppart SA

Subjects

Adult, Aged, Aged, 80 and over, Breast Neoplasms pathology, Carcinoma pathology, Equipment Design, Female, Humans, Incidence, Intraoperative Care instrumentation, Mastectomy, Segmental methods, Middle Aged, Neoplasm, Residual pathology, Neoplasm, Residual surgery, Sensitivity and Specificity, Single-Blind Method, Tomography, Optical Coherence instrumentation, Video Recording instrumentation, Video Recording methods, Breast Neoplasms surgery, Carcinoma surgery, Computer Systems, Intraoperative Care methods, Mastectomy methods, Neoplasm, Residual prevention & control, Tomography, Optical Coherence methods

Abstract

Wide local excision (WLE) is a common surgical intervention for solid tumors such as those in melanoma, breast, pancreatic, and gastrointestinal cancer. However, adequate margin assessment during WLE remains a significant challenge, resulting in surgical reinterventions to achieve adequate local control. Currently, no label-free imaging method is available for surgeons to examine the resection bed in vivo for microscopic residual cancer. Optical coherence tomography (OCT) enables real-time high-resolution imaging of tissue microstructure. Previous studies have demonstrated that OCT analysis of excised tissue specimens can distinguish between normal and cancerous tissues by identifying the heterogeneous and disorganized microscopic tissue structures indicative of malignancy. In this translational study involving 35 patients, a handheld surgical OCT imaging probe was developed for in vivo use to assess margins both in the resection bed and on excised specimens for the microscopic presence of cancer. The image results from OCT showed structural differences between normal and cancerous tissue within the resection bed following WLE of the human breast. The ex vivo images were compared with standard postoperative histopathology to yield sensitivity of 91.7% [95% confidence interval (CI), 62.5%-100%] and specificity of 92.1% (95% CI, 78.4%-98%). This study demonstrates in vivo OCT imaging of the resection bed during WLE with the potential for real-time microscopic image-guided surgery., (©2015 American Association for Cancer Research.)

Published

2015

24. Computational high-resolution optical imaging of the living human retina.

Author

Shemonski ND, South FA, Liu YZ, Adie SG, Carney PS, and Boppart SA

Abstract

High-resolution in vivo imaging is of great importance for the fields of biology and medicine. The introduction of hardware-based adaptive optics (HAO) has pushed the limits of optical imaging, enabling high-resolution near diffraction-limited imaging of previously unresolvable structures 1,2 . In ophthalmology, when combined with optical coherence tomography, HAO has enabled a detailed three-dimensional visualization of photoreceptor distributions 3,4 and individual nerve fibre bundles 5 in the living human retina. However, the introduction of HAO hardware and supporting software adds considerable complexity and cost to an imaging system, limiting the number of researchers and medical professionals who could benefit from the technology. Here we demonstrate a fully automated computational approach that enables high-resolution in vivo ophthalmic imaging without the need for HAO. The results demonstrate that computational methods in coherent microscopy are applicable in highly dynamic living systems.

Published

2015

25. Optical parametrically gated microscopy in scattering media.

Author

Zhao Y, Adie SG, Tu H, Liu Y, Graf BW, Chaney EJ, Marjanovic M, and Boppart SA

Subjects

Humans, Diagnostic Imaging instrumentation, Light, Microscopy instrumentation, Nephelometry and Turbidimetry instrumentation, Optics and Photonics, Scattering, Radiation, Tomography, Optical Coherence instrumentation

Abstract

High-resolution imaging in turbid media has been limited by the intrinsic compromise between the gating efficiency (removal of multiply-scattered light background) and signal strength in the existing optical gating techniques. This leads to shallow depths due to the weak ballistic signal, and/or degraded resolution due to the strong multiply-scattering background--the well-known trade-off between resolution and imaging depth in scattering samples. In this work, we employ a nonlinear optics based optical parametric amplifier (OPA) to address this challenge. We demonstrate that both the imaging depth and the spatial resolution in turbid media can be enhanced simultaneously by the OPA, which provides a high level of signal gain as well as an inherent nonlinear optical gate. This technology shifts the nonlinear interaction to an optical crystal placed in the detection arm (image plane), rather than in the sample, which can be used to exploit the benefits given by the high-order parametric process and the use of an intense laser field. The coherent process makes the OPA potentially useful as a general-purpose optical amplifier applicable to a wide range of optical imaging techniques.

Published

2014

26. Differentiation of ex vivo human breast tissue using polarization-sensitive optical coherence tomography.

Author

South FA, Chaney EJ, Marjanovic M, Adie SG, and Boppart SA

Abstract

Successful treatment of breast cancer typically requires surgical removal of the tumor. Optical coherence tomography (OCT) has been previously developed for real-time imaging of the surgical margin. However, it can be difficult to distinguish between normal stromal tissue and cancer tissue based on scattering intensity and structure alone. Polarization-sensitive optical coherence tomography (PS-OCT) is sensitive to form birefringence of biological tissue. We report on the development of a high-speed PS-OCT system and imaging of ex vivo human breast tissue, showing enhanced contrast between healthy and cancerous tissues based upon collagen content confirmed with corresponding histology. These results demonstrate the feasibility of using PS-OCT to supplement structural OCT as a possible method for intraoperative tumor margin evaluation.

Published

2014

27. Stability in computed optical interferometric tomography (Part II): in vivo stability assessment.

Author

Shemonski ND, Ahmad A, Adie SG, Liu YZ, South FA, Carney PS, and Boppart SA

Subjects

Female, Humans, Phantoms, Imaging, Reproducibility of Results, Interferometry methods, Tomography, Optical Coherence methods

Abstract

Stability is of utmost importance to a wide range of phase-sensitive processing techniques. In Doppler optical coherence tomography and optical coherence elastography, in addition to defocus and aberration correction techniques such as interferometric synthetic aperture microscopy and computational/digital adaptive optics, a precise understanding of the system and sample stability helps to guide the system design and choice of imaging parameters. This article focuses on methods to accurately and quantitatively measure the stability of an imaging configuration in vivo. These methods are capable of partially decoupling axial from transverse motion and are compared against the stability requirements for computed optical interferometric tomography laid out in the first part of this article.

Published

2014

28. Stability in computed optical interferometric tomography (part I): stability requirements.

Author

Shemonski ND, Adie SG, Liu YZ, South FA, Carney PS, and Boppart SA

Subjects

Computer Simulation, Image Processing, Computer-Assisted, Motion, Reproducibility of Results, Signal-To-Noise Ratio, Time Factors, Interferometry methods, Tomography, Optical Coherence methods

Abstract

As imaging systems become more advanced and acquire data at faster rates, increasingly dynamic samples can be imaged without concern of motion artifacts. For optical interferometric techniques such as optical coherence tomography, it often follows that initially, only amplitude-based data are utilized due to unstable or unreliable phase measurements. As systems progress, stable phase maps can also be acquired, enabling more advanced, phase-dependent post-processing techniques. Here we report an investigation of the stability requirements for a class of phase-dependent post-processing techniques - numerical defocus and aberration correction with further extensions to techniques such as Doppler, phase-variance, and optical coherence elastography. Mathematical analyses and numerical simulations over a variety of instabilities are supported by experimental investigations.

Published

2014

29. Computed optical interferometric tomography for high-speed volumetric cellular imaging.

Author

Liu YZ, Shemonski ND, Adie SG, Ahmad A, Bower AJ, Carney PS, and Boppart SA

Abstract

Three-dimensional high-resolution imaging methods are important for cellular-level research. Optical coherence microscopy (OCM) is a low-coherence-based interferometry technology for cellular imaging with both high axial and lateral resolution. Using a high-numerical-aperture objective, OCM normally has a shallow depth of field and requires scanning the focus through the entire region of interest to perform volumetric imaging. With a higher-numerical-aperture objective, the image quality of OCM is affected by and more sensitive to aberrations. Interferometric synthetic aperture microscopy (ISAM) and computational adaptive optics (CAO) are computed imaging techniques that overcome the depth-of-field limitation and the effect of optical aberrations in optical coherence tomography (OCT), respectively. In this work we combine OCM with ISAM and CAO to achieve high-speed volumetric cellular imaging. Experimental imaging results of ex vivo human breast tissue, ex vivo mouse brain tissue, in vitro fibroblast cells in 3D scaffolds, and in vivo human skin demonstrate the significant potential of this technique for high-speed volumetric cellular imaging.

Published

2014

30. Multifocal interferometric synthetic aperture microscopy.

Author

Xu Y, Chng XK, Adie SG, Boppart SA, and Carney PS

Subjects

Algorithms, Image Enhancement methods, Image Interpretation, Computer-Assisted methods, Interferometry instrumentation, Microscopy, Interference instrumentation, Tomography, Optical Coherence instrumentation

Abstract

There is an inherent trade-off between transverse resolution and depth of field (DOF) in optical coherence tomography (OCT) which becomes a limiting factor for certain applications. Multifocal OCT and interferometric synthetic aperture microscopy (ISAM) each provide a distinct solution to the trade-off through modification to the experiment or via post-processing, respectively. In this paper, we have solved the inverse problem of multifocal OCT and present a general algorithm for combining multiple ISAM datasets. Multifocal ISAM (MISAM) uses a regularized combination of the resampled datasets to bring advantages of both multifocal OCT and ISAM to achieve optimal transverse resolution, extended effective DOF and improved signal-to-noise ratio. We present theory, simulation and experimental results.

Published

2014

31. In vivo multimodal microscopy for detecting bone-marrow-derived cell contribution to skin regeneration.

Author

Graf BW, Bower AJ, Chaney EJ, Marjanovic M, Adie SG, De Lisio M, Valero MC, Boppart MD, and Boppart SA

Subjects

Animals, Keratinocytes cytology, Mice, Mice, Inbred C57BL, Multimodal Imaging, Optical Imaging, Skin Transplantation, Bone Marrow Cells cytology, Microscopy methods, Regeneration, Skin cytology, Skin Physiological Phenomena

Abstract

Bone-marrow (BM)-derived cells have been shown to be capable of aiding skin regeneration in vivo by differentiating into keratinocytes. However, the conditions under which this occurs are not fully understood. Characterizing innate mechanisms of skin regeneration by stem cells in vivo is important for the area of stem cell biology. In this study, we investigate the use of novel in vivo imaging technology for characterizing the contribution of BM-derived cells to regeneration of the epidermis in mouse skin in vivo. In vivo imaging provides the ability to non-invasively observe the spatial positions and morphology of the BM-derived cells. Using a GFP BM-transplanted mouse model and in vivo multimodal microscopy, BM-derived cells can be observed in the skin. Our in vivo imaging method was used to search for the presence and identify the 3D spatial distribution of BM-derived cells in the epidermis of the skin under normal conditions, following wound healing, and after syngeneic skin grafting. We did not observe any evidence of BM-derived keratinocytes under these conditions, but we did observe BM-derived dendritic cells in the skin grafts. In vivo multimodal imaging has great potential for characterizing the conditions under which BM-derived cells contribute to skin regeneration., (Copyright © 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

32. Three-dimensional optical coherence tomography for optical biopsy of lymph nodes and assessment of metastatic disease.

Author

John R, Adie SG, Chaney EJ, Marjanovic M, Tangella KV, and Boppart SA

Subjects

Animals, Female, Lymph Nodes surgery, Lymphatic Metastasis, Mammary Neoplasms, Animal surgery, Rats, Rats, Inbred F344, Imaging, Three-Dimensional, Lymph Nodes pathology, Mammary Neoplasms, Animal diagnosis, Tomography, Optical Coherence methods

Abstract

Background: Numerous techniques have been developed for localizing lymph nodes before surgical resection and for their histological assessment. Nondestructive high-resolution transcapsule optical imaging of lymph nodes offers the potential for in situ assessment of metastatic involvement, potentially during surgical procedures., Methods: Three-dimensional optical coherence tomography (3-D OCT) was used for imaging and assessing resected popliteal lymph nodes from a preclinical rat metastatic tumor model over a 9-day time-course study after tumor induction. The spectral-domain OCT system utilized a center wavelength of 800 nm, provided axial and transverse resolutions of 3 and 12 μm, respectively, and performed imaging at 10,000 axial scans per second., Results: OCT is capable of providing high-resolution label-free images of intact lymph node microstructure based on intrinsic optical scattering properties with penetration depths of ~1-2 mm. The results demonstrate that OCT is capable of differentiating normal, reactive, and metastatic lymph nodes based on microstructural changes. The optical scattering and structural changes revealed by OCT from day 3 to day 9 after the injection of tumor cells into the lymphatic system correlate with inflammatory and immunological changes observed in the capsule, precortical regions, follicles, and germination centers found during histopathology., Conclusions: We report for the first time a longitudinal study of 3-D transcapsule OCT imaging of intact lymph nodes demonstrating microstructural changes during metastatic infiltration. These results demonstrate the potential of OCT as a technique for intraoperative, real-time in situ 3-D optical biopsy of lymph nodes for the intraoperative staging of cancer.

Published

2013

33. Long-term time-lapse multimodal intravital imaging of regeneration and bone-marrow-derived cell dynamics in skin.

Author

Graf BW, Chaney EJ, Marjanovic M, Adie SG, De Lisio M, Valero MC, Boppart MD, and Boppart SA

Abstract

A major challenge for translating cell-based therapies is understanding the dynamics of cells and cell populations in complex in vivo environments. Intravital microscopy has shown great promise for directly visualizing cell behavior in vivo . However, current methods are limited to relatively short imaging times (hours), by ways to track cell and cell population dynamics over extended time-lapse periods (days to weeks to months), and by relatively few imaging contrast mechanisms that persist over extended investigations. We present technology to visualize and quantify complex, multifaceted dynamic changes in natural deformable skin over long time periods using novel multimodal imaging and a non-rigid image registration method. These are demonstrated in green fluorescent protein (GFP) bone marrow (BM) transplanted mice to study dynamic skin regeneration. This technology provides a novel perspective for studying dynamic biological processes and will enable future studies of stem, immune, and tumor cell biology in vivo .

Published

2013

34. Real-time in vivo computed optical interferometric tomography.

Author

Ahmad A, Shemonski ND, Adie SG, Kim HS, Hwu WM, Carney PS, and Boppart SA

Abstract

High-resolution real-time tomography of scattering tissues is important for many areas of medicine and biology 1-6 . However, the compromise between transverse resolution and depth-of-field in addition to low sensitivity deep in tissue continue to impede progress towards cellular-level volumetric tomography. Computed imaging has the potential to solve these long-standing limitations. Interferometric synthetic aperture microscopy (ISAM) 7-9 is a computed imaging technique enabling high-resolution volumetric tomography with spatially invariant resolution. However, its potential for clinical diagnostics remains largely untapped since full volume reconstructions required lengthy postprocessing, and the phase-stability requirements have been difficult to satisfy in vivo . Here we demonstrate how 3-D Fourier-domain resampling, in combination with high-speed optical coherence tomography (OCT), can achieve high-resolution in vivo tomography. Enhanced depth sensitivity was achieved over a depth-of-field extended in real time by more than an order of magnitude. This work lays the foundation for high-speed volumetric cellular-level tomography.

Published

2013

35. SEGMENTATION AND CORRELATION OF OPTICAL COHERENCE TOMOGRAPHY AND X-RAY IMAGES FOR BREAST CANCER DIAGNOSTICS.

Author

Sun JG, Adie SG, Chaney EJ, and Boppart SA

Abstract

Pre-operative X-ray mammography and intraoperative X-ray specimen radiography are routinely used to identify breast cancer pathology. Recent advances in optical coherence tomography (OCT) have enabled its use for the intraoperative assessment of surgical margins during breast cancer surgery. While each modality offers distinct contrast of normal and pathological features, there is an essential need to correlate image-based features between the two modalities to take advantage of the diagnostic capabilities of each technique. We compare OCT to X-ray images of resected human breast tissue and correlate different tissue features between modalities for future use in real-time intraoperative OCT imaging. X-ray imaging (specimen radiography) is currently used during surgical breast cancer procedures to verify tumor margins, but cannot image tissue in situ. OCT has the potential to solve this problem by providing intraoperative imaging of the resected specimen as well as the in situ tumor cavity. OCT and micro-CT (X-ray) images are automatically segmented using different computational approaches, and quantitatively compared to determine the ability of these algorithms to automatically differentiate regions of adipose tissue from tumor. Furthermore, two-dimensional (2D) and three-dimensional (3D) results are compared. These correlations, combined with real-time intraoperative OCT, have the potential to identify possible regions of tumor within breast tissue which correlate to tumor regions identified previously on X-ray imaging (mammography or specimen radiography).

Published

2013

36. Dynamic method of optical coherence elastography in determining viscoelasticity of polymers and tissues.

Author

Wang Y, Shemonski ND, Adie SG, Boppart SA, and Insana MF

Subjects

Animals, Elastic Modulus, Gelatin chemistry, Gels chemistry, Phantoms, Imaging, Rheology, Swine, Viscosity, Elasticity Imaging Techniques instrumentation, Liver diagnostic imaging, Polymers chemistry

Abstract

In this paper, we report on a novel quantitative elastography technique that combines optical coherence tomography (OCT) with acoustic radiation force (ARF) excitation to estimate the complex modulus. Sinusoidally modulated ARF excitations between 200 - 4000 Hz generate a surface wave at the tissue surface that can be related to bulk viscoelastic (VE) properties in a manner that is both precise and quantitative. This method is very well suited to studying media at high spatial resolution and over a very broad range of force frequencies. Mechanical characterization was calibrated using hydropolymers before studying liver samples. Fresh porcine liver samples were measured over time with and without formalin fixation. These data were used to evaluate the utility of the Kelvin-Voigt rheological model commonly used to fit dispersion data when estimating modulus values. We also investigated use of square-wave force excitation to measure the step response of tissues.

Published

2013

37. Guide-star-based computational adaptive optics for broadband interferometric tomography.

Author

Adie SG, Shemonski ND, Graf BW, Ahmad A, Scott Carney P, and Boppart SA

Abstract

We present a method for the numerical correction of optical aberrations based on indirect sensing of the scattered wavefront from point-like scatterers ("guide stars") within a three-dimensional broadband interferometric tomogram. This method enables the correction of high-order monochromatic and chromatic aberrations utilizing guide stars that are revealed after numerical compensation of defocus and low-order aberrations of the optical system. Guide-star-based aberration correction in a silicone phantom with sparse sub-resolution-sized scatterers demonstrates improvement of resolution and signal-to-noise ratio over a large isotome. Results in highly scattering muscle tissue showed improved resolution of fine structure over an extended volume. Guide-star-based computational adaptive optics expands upon the use of image metrics for numerically optimizing the aberration correction in broadband interferometric tomography, and is analogous to phase-conjugation and time-reversal methods for focusing in turbid media.

Published

2012

38. Computational adaptive optics for broadband optical interferometric tomography of biological tissue.

Author

Adie SG, Graf BW, Ahmad A, Carney PS, and Boppart SA

Subjects

Algorithms, Animals, Image Processing, Computer-Assisted instrumentation, Imaging, Three-Dimensional instrumentation, Imaging, Three-Dimensional methods, Microscopy, Interference instrumentation, Phantoms, Imaging, Rats, Reproducibility of Results, Tomography, Optical Coherence instrumentation, Image Processing, Computer-Assisted methods, Lung anatomy & histology, Microscopy, Interference methods, Tomography, Optical Coherence methods

Abstract

Aberrations in optical microscopy reduce image resolution and contrast, and can limit imaging depth when focusing into biological samples. Static correction of aberrations may be achieved through appropriate lens design, but this approach does not offer the flexibility of simultaneously correcting aberrations for all imaging depths, nor the adaptability to correct for sample-specific aberrations for high-quality tomographic optical imaging. Incorporation of adaptive optics (AO) methods have demonstrated considerable improvement in optical image contrast and resolution in noninterferometric microscopy techniques, as well as in optical coherence tomography. Here we present a method to correct aberrations in a tomogram rather than the beam of a broadband optical interferometry system. Based on Fourier optics principles, we correct aberrations of a virtual pupil using Zernike polynomials. When used in conjunction with the computed imaging method interferometric synthetic aperture microscopy, this computational AO enables object reconstruction (within the single scattering limit) with ideal focal-plane resolution at all depths. Tomographic reconstructions of tissue phantoms containing subresolution titanium-dioxide particles and of ex vivo rat lung tissue demonstrate aberration correction in datasets acquired with a highly astigmatic illumination beam. These results also demonstrate that imaging with an aberrated astigmatic beam provides the advantage of a more uniform depth-dependent signal compared to imaging with a standard gaussian beam. With further work, computational AO could enable the replacement of complicated and expensive optical hardware components with algorithms implemented on a standard desktop computer, making high-resolution 3D interferometric tomography accessible to a wider group of users and nonspecialists.

Published

2012

39. In vivo three-dimensional optical coherence elastography.

Author

Kennedy BF, Liang X, Adie SG, Gerstmann DK, Quirk BC, Boppart SA, and Sampson DD

Subjects

Equipment Design, Equipment Failure Analysis, Humans, Reproducibility of Results, Sensitivity and Specificity, Dermoscopy instrumentation, Elasticity Imaging Techniques instrumentation, Image Enhancement instrumentation, Skin diagnostic imaging, Skin Physiological Phenomena, Tomography, Optical Coherence instrumentation

Abstract

We present the first three-dimensional (3D) data sets recorded using optical coherence elastography (OCE). Uni-axial strain rate was measured on human skin in vivo using a spectral-domain optical coherence tomography (OCT) system providing >450 times higher line rate than previously reported for in vivo OCE imaging. Mechanical excitation was applied at a frequency of 125 Hz using a ring actuator sample arm with, for the first time in OCE measurements, a controlled static preload. We performed 3D-OCE, processed in 2D and displayed in 3D, on normal and hydrated skin and observed a more elastic response of the stratum corneum in the hydrated case.

Published

2011

40. Spectroscopic optical coherence elastography.

Author

Adie SG, Liang X, Kennedy BF, John R, Sampson DD, and Boppart SA

Subjects

Animals, Cell Line, Tumor, Elastic Modulus, Equipment Design, Equipment Failure Analysis, Image Enhancement instrumentation, Image Enhancement methods, Phantoms, Imaging, Rats, Reproducibility of Results, Sensitivity and Specificity, Breast Neoplasms diagnosis, Breast Neoplasms physiopathology, Elasticity Imaging Techniques instrumentation, Image Interpretation, Computer-Assisted instrumentation, Image Interpretation, Computer-Assisted methods, Spectrum Analysis instrumentation, Tomography, Optical Coherence instrumentation

Abstract

We present an optical technique to image the frequency-dependent complex mechanical response of a viscoelastic sample. Three-dimensional hyperspectral data, comprising two-dimensional B-mode images and a third dimension corresponding to vibration frequency, were acquired from samples undergoing external mechanical excitation in the audio-frequency range. We describe the optical coherence tomography (OCT) signal when vibration is applied to a sample and detail the processing and acquisition techniques used to extract the local complex mechanical response from three-dimensional data that, due to a wide range of vibration frequencies, possess a wide range of sample velocities. We demonstrate frequency-dependent contrast of the displacement amplitude and phase of a silicone phantom containing inclusions of higher stiffness. Measurements of an ex vivo tumor margin demonstrate distinct spectra between adipose and tumor regions, and images of displacement amplitude and phase demonstrated spatially-resolved contrast. Contrast was also observed in displacement amplitude and phase images of a rat muscle sample. These results represent the first demonstration of mechanical spectroscopy based on B-mode OCT imaging. Spectroscopic optical coherence elastography (S-OCE) provides a high-resolution imaging capability for the detection of tissue pathologies that are characterized by a frequency-dependent viscoelastic response.

Published

2010

41. Correction of coherence gate curvature in high numerical aperture optical coherence imaging.

Author

Graf BW, Adie SG, and Boppart SA

Subjects

Epidermis, Humans, Artifacts, Tomography, Optical Coherence methods

Abstract

We present a method for correcting coherence gate curvature caused by scanning-induced path length variations in spectral-domain high-NA optical coherence imaging systems. These variations cause curvature artifacts in optical coherence tomography and effectively restrict the field of view in optical coherence microscopy (OCM). Here we show that the coherence gate curvature can be measured and corrected by recovering the phase of the analytic signal from a calibration image. This phase information can be used directly to process OCM images allowing the coherence gate curvature, as well as any order of system dispersion, to be corrected in a computationally efficient manner. We also discuss the use of various image quality metrics that can be used to adjust the calibrated phase in order to keep the coherence and confocal gates aligned in tissue.

Published

2010

42. Dynamic spectral-domain optical coherence elastography for tissue characterization.

Author

Liang X, Adie SG, John R, and Boppart SA

Subjects

Animals, Biomarkers, Tumor pharmacology, Equipment Design, Female, Mammary Neoplasms, Animal chemically induced, Methylnitrosourea pharmacology, Models, Theoretical, Phantoms, Imaging, Rats, Rats, Inbred WF, Scattering, Radiation, Silicones, Elasticity Imaging Techniques instrumentation, Elasticity Imaging Techniques methods, Mammary Neoplasms, Animal pathology, Tomography, Optical Coherence instrumentation, Tomography, Optical Coherence methods

Abstract

A dynamic spectral-domain optical coherence elastography (OCE) imaging technique is reported. In this technique, audio-frequency compressive vibrations are generated by a piezoelectric stack as external excitation, and strain rates in the sample are calculated and mapped quantitatively using phase-sensitive spectral-domain optical coherence tomography. At different driving frequencies, this technique provides contrast between sample regions with different mechanical properties, and thus is used to mechanically characterize tissue. We present images of a three-layer silicone tissue phantom and rat tumor tissue ex vivo, based on quantitative strain rate. Both acquisition speed and processing speed are improved dramatically compared with previous OCE imaging techniques. With high resolution, high acquisition speed, and the ability to characterize the mechanical properties of tissue, this OCE technique has potential use in non-destructive volumetric imaging and clinical applications.

Published

2010

43. Cross-validation of interferometric synthetic aperture microscopy and optical coherence tomography.

Author

Ralston TS, Adie SG, Marks DL, Boppart SA, and Carney PS

Subjects

Adipose Tissue, Animals, Image Processing, Computer-Assisted, Lenses, Rats, Interferometry methods, Microscopy methods, Tomography, Optical Coherence methods

Abstract

Computationally reconstructed interferometric synthetic aperture microscopy is coregistered with optical coherence tomography (OCT) focal plane data to provide quantitative cross validation with OCT. This is accomplished through a qualitative comparison of images and a quantitative analysis of the width of the point-spread function in simulation and experiment. The width of the ISAM point-spread function is seen to be independent of depth, in contrast to OCT.

Published

2010

44. Sonification of optical coherence tomography data and images.

Author

Ahmad A, Adie SG, Wang M, and Boppart SA

Subjects

Algorithms, Image Interpretation, Computer-Assisted methods, Information Storage and Retrieval methods, Pattern Recognition, Automated methods, Sound Spectrography methods, Tomography, Optical Coherence methods, User-Computer Interface

Abstract

Sonification is the process of representing data as non-speech audio signals. In this manuscript, we describe the auditory presentation of OCT data and images. OCT acquisition rates frequently exceed our ability to visually analyze image-based data, and multi-sensory input may therefore facilitate rapid interpretation. This conversion will be especially valuable in time-sensitive surgical or diagnostic procedures. In these scenarios, auditory feedback can complement visual data without requiring the surgeon to constantly monitor the screen, or provide additional feedback in non-imaging procedures such as guided needle biopsies which use only axial-scan data. In this paper we present techniques to translate OCT data and images into sound based on the spatial and spatial frequency properties of the OCT data. Results obtained from parameter-mapped sonification of human adipose and tumor tissues are presented, indicating that audio feedback of OCT data may be useful for the interpretation of OCT images., ((c) 2010 Optical Society of America.)

Published

2010

45. In vivo magnetomotive optical molecular imaging using targeted magnetic nanoprobes.

Author

John R, Rezaeipoor R, Adie SG, Chaney EJ, Oldenburg AL, Marjanovic M, Haldar JP, Sutton BP, and Boppart SA

Subjects

Animals, Female, Humans, Magnetic Resonance Imaging, Microscopy, Electron, Transmission, Models, Animal, Nanostructures ultrastructure, Neoplasms diagnosis, Rats, Rats, Inbred WF, Receptor, ErbB-2 analysis, Contrast Media analysis, Magnetics, Nanostructures analysis, Neoplasms chemistry, Tomography, Optical Coherence methods

Abstract

Dynamic magnetomotion of magnetic nanoparticles (MNPs) detected with magnetomotive optical coherence tomography (MM-OCT) represents a new methodology for contrast enhancement and therapeutic interventions in molecular imaging. In this study, we demonstrate in vivo imaging of dynamic functionalized iron oxide MNPs using MM-OCT in a preclinical mammary tumor model. Using targeted MNPs, in vivo MM-OCT images exhibit strong magnetomotive signals in mammary tumor, and no significant signals were measured from tumors of rats injected with nontargeted MNPs or saline. The results of in vivo MM-OCT are validated by MRI, ex vivo MM-OCT, Prussian blue staining of histological sections, and immunohistochemical analysis of excised tumors and internal organs. The MNPs are antibody functionalized to target the human epidermal growth factor receptor 2 (HER2 neu) protein. Fc-directed conjugation of the antibody to the MNPs aids in reducing uptake by macrophages in the reticulo-endothelial system, thereby increasing the circulation time in the blood. These engineered magnetic nanoprobes have multifunctional capabilities enabling them to be used as dynamic contrast agents in MM-OCT and MRI.

Published

2010

46. Optical coherence tomography: the intraoperative assessment of lymph nodes in breast cancer.

Author

Nguyen FT, Zysk AM, Chaney EJ, Adie SG, Kotynek JG, Oliphant UJ, Bellafiore FJ, Rowland KM, Johnson PA, and Boppart SA

Subjects

Breast Neoplasms surgery, Female, Humans, Intraoperative Care, Lymphatic Metastasis, Breast Neoplasms pathology, Breast Neoplasms secondary, Lymph Node Excision methods, Lymph Nodes pathology, Lymph Nodes surgery, Surgery, Computer-Assisted methods

Abstract

During breast-conserving surgeries, axillary lymph nodes draining from the primary tumor site are removed for disease staging. Although a high number of lymph nodes are often resected during sentinel and lymph-node dissections, only a relatively small percentage of nodes are found to be metastatic, a fact that must be weighed against potential complications such as lymphedema. Without a real-time in vivo or in situ intraoperative imaging tool to provide a microscopic assessment of the nodes, postoperative paraffin section histopathological analysis currently remains the gold standard in assessing the status of lymph nodes. This paper investigates the use of optical coherence tomography (OCT), a high-resolution real-time microscopic optical-imaging technique, for the intraoperative ex vivo imaging and assessment of axillary lymph nodes. Normal (13), reactive (1), and metastatic (3) lymph nodes from 17 human patients with breast cancer were imaged intraoperatively with OCT. These preliminary clinical studies have identified scattering changes in the cortex, relative to the capsule, which can be used to differentiate normal from reactive and metastatic nodes. These optical scattering changes are correlated with inflammatory and immunological changes observed in the follicles and germinal centers. These results suggest that intraoperative OCT has the potential to assess the real-time node status in situ, without having to physically resect and histologically process specimens to visualize microscopic features.

Published

2010

47. Fc-DIRECTED ANTIBODY CONJUGATION OF MAGNETIC NANOPARTICLES FOR ENHANCED MOLECULAR TARGETING.

Author

Rezaeipoor R, John R, Adie SG, Chaney EJ, Marjanovic M, Oldenburg AL, Rinne SA, and Boppart SA

Abstract

In this study, we report the fabrication of engineered iron oxide magnetic nanoparticles (MNPs) functionalized with anti-human epidermal growth factor receptor type 2 (HER2) antibody to target the tumor antigen HER2. The Fc-directed conjugation of antibodies to the MNPs aids their efficient immunospecific targeting through free Fab portions. The directional specificity of conjugation was verified on a macrophage cell line. Immunofluorescence studies on macrophages treated with functionalized MNPs and free anti-HER2 antibody revealed that the antibody molecules bind to the MNPs predominantly through their Fc portion. Different cell lines with different HER2 expression levels were used to test the specificity of our functionalized nanoprobe for molecular targeting applications. The results of cell line targeting demonstrate that these engineered MNPs are able to differentiate between cell lines with different levels of HER2 expression.

Published

2009

48. Audio frequency in vivo optical coherence elastography.

Author

Adie SG, Kennedy BF, Armstrong JJ, Alexandrov SA, and Sampson DD

Subjects

Elasticity Imaging Techniques instrumentation, Feasibility Studies, Phantoms, Imaging, Reproducibility of Results, Sensitivity and Specificity, Tomography, Optical Coherence instrumentation, Acoustic Stimulation methods, Algorithms, Elasticity Imaging Techniques methods, Image Enhancement methods, Image Interpretation, Computer-Assisted methods, Skin diagnostic imaging, Tomography, Optical Coherence methods

Abstract

We present a new approach to optical coherence elastography (OCE), which probes the local elastic properties of tissue by using optical coherence tomography to measure the effect of an applied stimulus in the audio frequency range. We describe the approach, based on analysis of the Bessel frequency spectrum of the interferometric signal detected from scatterers undergoing periodic motion in response to an applied stimulus. We present quantitative results of sub-micron excitation at 820 Hz in a layered phantom and the first such measurements in human skin in vivo.

Published

2009

49. Cross-correlation-based image acquisition technique for manually-scanned optical coherence tomography.

Author

Ahmad A, Adie SG, Chaney EJ, Sharma U, and Boppart SA

Subjects

Adipose Tissue anatomy & histology, Algorithms, Breast anatomy & histology, Female, Humans, Phantoms, Imaging, Silicones, Titanium, Imaging, Three-Dimensional methods, Tomography, Optical Coherence methods

Abstract

We present a novel image acquisition technique for Optical Coherence Tomography (OCT) that enables manual lateral scanning. The technique compensates for the variability in lateral scan velocity based on feedback obtained from correlation between consecutive A-scans. Results obtained from phantom samples and biological tissues demonstrate successful assembly of OCT images from manually-scanned datasets despite non-uniform scan velocity and abrupt stops encountered during data acquisition. This technique could enable the acquisition of images during manual OCT needle-guided biopsy or catheter-based imaging, and for assembly of large field-of-view images with hand-held probes during intraoperative in vivo OCT imaging.

Published

2009

50. Three-dimensional optical coherence tomography of whole-muscle autografts as a precursor to morphological assessment of muscular dystrophy in mice.

Author

Klyen BR, Armstrong JJ, Adie SG, Radley HG, Grounds MD, and Sampson DD

Subjects

Algorithms, Animals, Feasibility Studies, Female, Graft Rejection etiology, Image Enhancement methods, Mice, Mice, Inbred C57BL, Reproducibility of Results, Sensitivity and Specificity, Disease Models, Animal, Graft Rejection pathology, Image Interpretation, Computer-Assisted methods, Imaging, Three-Dimensional methods, Muscle, Skeletal pathology, Muscle, Skeletal transplantation, Muscular Dystrophies pathology

Abstract

Three-dimensional optical coherence tomography (3D-OCT) is used to evaluate the structure and pathology of regenerating mouse skeletal muscle autografts for the first time. The death of myofibers with associated inflammation and subsequent new muscle formation in this graft model represents key features of necrosis and inflammation in the human disease Duchenne muscular dystrophy. We perform 3D-OCT imaging of excised autografts and compare OCT images with coregistered histology. The OCT images readily distinguish the necrotic and inflammatory tissue of the graft from the intact healthy muscle fibers in the underlying host tissue. These preliminary findings suggest that, with further development, 3D-OCT could be used as a tool for the evaluation of small-animal muscle morphology and pathology, in particular, for analysis of mouse models of muscular dystrophy.

Published

2008