Your search keyword '"ocis:(110.0180) Microscopy"' showing total 9 results

1. Determination of chronological aging parameters in epidermal keratinocytes by in vivo harmonic generation microscopy

Author

Chi-Kuang Sun, Sin Yo Chou, Pei-Hsun Wang, Ming Rung Tsai, Szu Yu Chen, and Yi-Hua Liao

Subjects

Pathology, medicine.medical_specialty, Dermatological Applications, integumentary system, business.industry, ocis:(190.4160) Multiharmonic generation, Atomic and Molecular Physics, and Optics, Intrinsic and extrinsic aging, ocis:(110.0180) Microscopy, Skin Aging, law.invention, Basal (phylogenetics), ocis:(170.1610) Clinical applications, In vivo, Confocal microscopy, law, Microscopy, medicine, ocis:(170.1530) Cell analysis, ocis:(170.1870) Dermatology, High harmonic generation, ocis:(170.3880) Medical and biological imaging, business, Preclinical imaging, Biotechnology

Abstract

Skin aging is an important issue in geriatric and cosmetic dermatology. To quantitatively analyze changes in keratinocytes related to intrinsic aging, we exploited a 1230 nm-based in vivo harmonic generation microscopy, combining second- and third-harmonic generation modalities. 52 individuals (21 men and 31 women, age range 19-79) were examined on the sun-protected volar forearm. Through quantitative analysis by the standard algorithm provided, we found that the cellular and nuclear size of basal keratinocytes, but not that of granular cells, was significantly increased with advancing age. The cellular and nuclear areas, which have an increase of 0.51 μm(2) and 0.15 μm(2) per year, respectively, can serve as scoring indices for intrinsic skin aging.

Published

2012

2. Cell imaging beyond the diffraction limit using sparse deconvolution spatial light interference microscopy

Author

Gabriel Popescu, Minh N. Do, Zhuo Wang, and S. Derin Babacan

Subjects

Physics, Image formation, Microscopy, business.industry, Resolution (electron density), ocis:(100.5070) Phase retrieval, Image processing, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Atomic and Molecular Physics, and Optics, Interference microscopy, ocis:(110.0180) Microscopy, 010309 optics, ocis:(100.6640) Superresolution, ocis:(100.1830) Deconvolution, Optics, Live cell imaging, 0103 physical sciences, Deconvolution, 0210 nano-technology, business, Biological imaging, Image resolution, Biotechnology

Abstract

We present an imaging method, dSLIM, that combines a novel deconvolution algorithm with spatial light interference microscopy (SLIM), to achieve 2.3x resolution enhancement with respect to the diffraction limit. By exploiting the sparsity of the phase images, which is prominent in many biological imaging applications, and modeling of the image formation via complex fields, the very fine structures can be recovered which were blurred by the optics. With experiments on SLIM images, we demonstrate that significant improvements in spatial resolution can be obtained by the proposed approach. Moreover, the resolution improvement leads to higher accuracy in monitoring dynamic activity over time. Experiments with primary brain cells, i.e. neurons and glial cells, reveal new subdiffraction structures and motions. This new information can be used for studying vesicle transport in neurons, which may shed light on dynamic cell functioning. Finally, the method is flexible to incorporate a wide range of image models for different applications and can be utilized for all imaging modalities acquiring complex field images.

Published

2011

3. How to integrate a micropipette into a closed microfluidic system : absorption spectra of an optically trapped erythrocyte

Author

Kerstin Ramser and Ahmed Alrifaiy

Subjects

Chemical content, Materials science, ocis:(300.1030) Absorption, Absorption spectroscopy, Spectrometer, Microfluidics, Pipette, Nanotechnology, ocis:(350.4855) Optical tweezers or optical manipulation, Atomic and Molecular Physics, and Optics, ocis:(110.0180) Microscopy, Optical tweezers, Microscopy, Other Medical Engineering, ocis:(220.4000) Microstructure fabrication, ocis:(170.3880) Medical and biological imaging, Annan medicinteknik, Absorption (electromagnetic radiation), ocis:(280.2490) Flow diagnostics, Biotechnology

Abstract

In July 2011 a new concept of a closed microfluidic system equipped with a fixed micropipette, optical tweezers and a UV-Vis spectrometer was presented [Biomed. Opt. Express 2, 2299 (2011)]. Figure 1 showed falsely oriented mirrors. To clarify the design of the setup, this erratum presents a correct schematic We present a new concept of integrating a micropipette within a closed microfluidic system equipped with optical tweezers and a UV-Vis spectrometer. A single red blood cell (RBC) was optically trapped and steered in three dimensions towards a micropipette that was integrated in the microfluidic system. Different oxygenation states of the RBC, triggered by altering the oxygen content in the microchannels through a pump system, were optically monitored by a UV-Vis spectrometer. The built setup is aimed to act as a multifunctional system where the biochemical content and the electrophysiological reaction of a single cell can be monitored simultaneously. The system can be used for other applications like single cell sorting, in vitro fertilization or electrophysiological experiments with precise environmental control of the gas-, and chemical content. Validerad; 2011; 20110721 (ahmahm)

Published

2011

4. Practical implementation of log-scale active illumination microscopy

Author

Kengyeh K. Chu, Daryl Lim, and Jerome Mertz

Subjects

Logarithmic scale, Microscope, Channel (digital image), Scale (ratio), Image quality, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Nanotechnology, Iterative reconstruction, ocis:(110.0180) Microscopy, law.invention, Scanning probe microscopy, Optics, law, Microscopy, Computer vision, ComputingMethodologies_COMPUTERGRAPHICS, Dynamic range, business.industry, Bright-field microscopy, Scanning confocal electron microscopy, Dark field microscopy, Atomic and Molecular Physics, and Optics, Noise, ocis:(180.5810) Scanning microscopy, Light sheet fluorescence microscopy, ocis:(190.4180) Multiphoton processes, ocis:(180.2520) Fluorescence microscopy, Artificial intelligence, business, Biotechnology

Abstract

Active illumination microscopy (AIM) is a method of redistributing dynamic range in a scanning microscope using real-time feedback to control illumination power on a sub-pixel time scale. We describe and demonstrate a fully integrated instrument that performs both feedback and image reconstruction. The image is reconstructed on a logarithmic scale to accommodate the dynamic range benefits of AIM in a single output channel. A theoretical and computational analysis of the influence of noise on active illumination feedback is presented, along with imaging examples illustrating the benefits of AIM. While AIM is applicable to any type of scanning microscope, we apply it here specifically to two-photon microscopy.

Published

2010

5. Optical coherence tomography-based freeze-drying microscopy

Author

Mircea Mujat, Kristyn Greco, Kristin L. Galbally-Kinney, Daniel X. Hammer, R. Daniel Ferguson, Nicusor Iftimia, Phillip Mulhall, Puneet Sharma, Michael J. Pikal, and William J. Kessler

Subjects

Light transmission, Materials science, genetic structures, Tissue imaging, Nanotechnology, 02 engineering and technology, 01 natural sciences, ocis:(110.0180) Microscopy, 010309 optics, Freeze-drying, Optical coherence tomography, ocis:(180.6900) Three-dimensional microscopy, 0103 physical sciences, Microscopy, medicine, Composite material, medicine.diagnostic_test, ocis:(110.4500) Optical coherence tomography, 021001 nanoscience & nanotechnology, eye diseases, Atomic and Molecular Physics, and Optics, Three dimensional imaging, Product (mathematics), sense organs, Optical Coherence Tomography, 0210 nano-technology, Biotechnology

Abstract

A new type of freeze-drying microscope based upon time-domain optical coherence tomography is presented here (OCT-FDM). The microscope allows for real-time, in situ 3D imaging of pharmaceutical formulations in vials relevant for manufacturing processes with a lateral resolution of

Published

2011

6. Nomarski serial time-encoded amplified microscopy for high-speed contrast-enhanced imaging of transparent media

Author

Ata Mahjoubfar, Ali Fard, Daniel R. Gossett, Dino Di Carlo, Bahram Jalali, and Keisuke Goda

Subjects

Microscopy, Materials science, business.industry, Semiconductor device fabrication, media_common.quotation_subject, ocis:(180.3170) Interference microscopy, Phase-contrast imaging, Optical Physics, Materials Engineering, Frame rate, ocis:(110.0180) Microscopy, Atomic and Molecular Physics, and Optics, Interference microscopy, Shutter speed, ocis:(320.7160) Ultrafast technology, Optics, (320.7160) Ultrafast technology, (180.3170) Interference microscopy, Contrast (vision), (110.0180) Microscopy, business, Serial time-encoded amplified microscopy, Biotechnology, media_common

Abstract

High-speed high-contrast imaging modalities that enable image acquisition of transparent media without the need for chemical staining are essential tools for a broad range of applications; from semiconductor process monitoring to blood screening. Here we introduce a method for contrast-enhanced imaging of unstained transparent objects that is capable of high-throughput imaging. This method combines the Nomarski phase contrast capability with the ultrahigh frame rate and shutter speed of serial time-encoded amplified microscopy. As a proof of concept, we show imaging of a transparent test structure and white blood cells in flow at a shutter speed of 33 ps and a frame rate of 36.1 MHz using a single-pixel photo-detector. This method is expected to be a valuable tool for high-throughput screening of unstained cells.

Published

2011

7. Fast macro-scale transmission imaging of microvascular networks using KESM

Author

John Keyser, David Mayerich, Yoonsuck Choe, Chul Sung, Louise C. Abbott, and Jaerock Kwon

Subjects

Pathology, medicine.medical_specialty, ocis:(170.1020) Ablation of tissue, Computer science, Image quality, Image processing, ocis:(110.0180) Microscopy, 03 medical and health sciences, 0302 clinical medicine, Microscopy, medicine, Segmentation, 030304 developmental biology, 0303 health sciences, Resolution (electron density), Blood flow, Atomic and Molecular Physics, and Optics, Transmission (telecommunications), Macroscopic scale, ocis:(170.3880) Medical and biological imaging, ocis:(179.6900) Three-dimensional microscopy, ocis:(170.2945) Illumination design, 030217 neurology & neurosurgery, Biotechnology, Biomedical engineering

Abstract

Accurate microvascular morphometric information has significant implications in several fields, including the quantification of angiogenesis in cancer research, understanding the immune response for neural prosthetics, and predicting the nature of blood flow as it relates to stroke. We report imaging of the whole mouse brain microvascular system at resolutions sufficient to perform accurate morphometry. Imaging was performed using Knife-Edge Scanning Microscopy (KESM) and is the first example of this technique that can be directly applied to clinical research. We are able to achieve ≈ 0.7μm resolution laterally with 1μm depth resolution using serial sectioning. No alignment was necessary and contrast was sufficient to allow segmentation and measurement of vessels.

Published

2011

8. Realistic 3D coherent transfer function inverse filtering of complex fields

Author

Isabelle Bergoënd, M. Fatih Toy, Yann Cotte, Shan Shan Kou, Cristian Arfire, Daniel Boss, and Christian Depeursinge

Subjects

Point spread function, Image formation, Computer science, Image processing, ocis:(090.1995) Digital holography, 02 engineering and technology, 01 natural sciences, ocis:(110.0180) Microscopy, 010309 optics, Diffraction tomography, Optics, ocis:(100.6890) Three-dimensional image processing, ocis:(180.6900) Three-dimensional microscopy, 0103 physical sciences, [MVD], business.industry, ocis:(100.5070) Phase retrieval, 021001 nanoscience & nanotechnology, Coherent diffraction imaging, Atomic and Molecular Physics, and Optics, ocis:(100.1830) Deconvolution, Scattering theory, Deconvolution, 0210 nano-technology, business, Phase retrieval, Image Reconstruction and Inverse Problems, Biotechnology

Abstract

We present a novel technique for three-dimensional (3D) image processing of complex fields. It consists in inverting the coherent image formation by filtering the complex spectrum with a realistic 3D coherent transfer function (CTF) of a high-NA digital holographic microscope. By combining scattering theory and signal processing, the method is demonstrated to yield the reconstruction of a scattering object field. Experimental reconstructions in phase and amplitude are presented under non-design imaging conditions. The suggested technique is best suited for an implementation in high-resolution diffraction tomography based on sample or illumination rotation.

Published

2011

9. Development of a versatile two-photon endoscope for biological imaging

Author

Youbo Zhao, Robert J. Gordon, and Hiroshi Nakamura

Subjects

Microscope, Materials science, 02 engineering and technology, 01 natural sciences, ocis:(110.0180) Microscopy, law.invention, 010309 optics, Optics, Two-photon excitation microscopy, law, 0103 physical sciences, Microscopy, ocis:(170.2150) Endoscopic imaging, ocis:(170.0110) Imaging systems, ocis:(110.2350) Fiber optics imaging, business.industry, 021001 nanoscience & nanotechnology, Laser, Cladding (fiber optics), Atomic and Molecular Physics, and Optics, Numerical aperture, ocis:(180.5810) Scanning microscopy, Achromatic lens, sense organs, 0210 nano-technology, Biological imaging, business, Endoscopes, Catheters and Micro-Optics, Biotechnology

Abstract

We describe a versatile, catheter-type two-photon probe, designed for in vivo and ex vivo imaging of the aqueous outflow pathway in the eye. The device consists of a silica double cladding fiber used for laser delivery and fluorescence collection, a spiral fiber scanner driven by a miniature piezoelectric tube, and an assembly of three micro-size doublet achromatic lenses used for focusing the laser and collecting the two-photon excitation signal. All the components have a maximum diameter of 2 mm and are enclosed in a length of 12-gauge stainless steel hypodermic tubing having an outer diameter of 2.8 mm. The lateral and axial resolutions of the probe are measured to be 1.5 μm and 9.2 μm, respectively. Different lens configurations and fibers are evaluated by comparing their spatial resolutions and fluorescence signal collection efficiencies. Doublet achromatic lenses and a double cladding fiber with a high inner cladding numerical aperture are found to produce a high signal collection efficiency, which is essential for imaging live tissues. Simple methods for reducing image distortions are demonstrated. Images of human trabecular meshwork tissue are successfully obtained with this miniature two-photon microscope.

Published

2010