Two-photon fluorescence microscope with a hollow-core photonic crystal fiber

Tai, Shih Peng; Chan, Ming-Che; Tsai, Tsung Han; Guol, Shi Hao; Chen, Li Jin; Sun, Chia‐Liang

doi:10.1117/12.588474

Cited by 14 publications

(18 citation statements)

References 14 publications

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“…PCF has various potential applications in nonlinear microscopy imaging and telecommunications areas, since it has better optical characteristics than TIR-based optical fibers in terms of guiding, dispersion, and refraction (Lourtioz, 2005). It has been shown that the dispersion of ultrafast optical pulses can be significantly reduced by using photonic crystal fibers (Gobel and others, 2004; Kim and others, 2005; McConnell and Riis, 2004; Tai and others, 2004). Importantly, photonic crystal fibers also offer better performance than traditional fibers in conducting high power ultrafast optical pulses.…”

Section: Introductionmentioning

confidence: 99%

Ultrafast optical pulse delivery with fibers for nonlinear microscopy

Kim

Choi

Yazdanfar

et al. 2008

Microscopy Res & Technique

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Nonlinear microscopies including multiphoton excitation fluorescence microscopy and multipleharmonic generation microscopy have recently gained popularity for cellular and tissue imaging. The optimization of these imaging methods for minimally invasive use will require optical fibers to conduct light into tight space where free space delivery is difficult. The delivery of high peak power laser pulses with optical fibers is limited by dispersion resulting from nonlinear refractive index responses. In this paper, we characterize a variety of commonly used optical fibers in terms of how they affect pulse profile and imaging performance of nonlinear microscopy; the following parameters are quantified: spectral bandwidth and temporal pulse width, two-photon excitation efficiency, and optical resolution. A theoretical explanation for the measured performance of these is also provided.

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Section: Introductionmentioning

confidence: 99%

Ultrafast optical pulse delivery with fibers for nonlinear microscopy

Kim

Choi

Yazdanfar

et al. 2008

Microscopy Res & Technique

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“…We observe minimal pulse broadening from 750 to 800 nm with 100 fs pulse width input. However, some prior studies [13][14] indicate that pulse broadening is closely related to GVD and is quite large in the similar range of wavelength for hollow core photonic bandgap crystal fiber but using an input pulse width of 200 fs. Therefore, the pulse propagation equation should be examined in detail in order to explain the discrepancy between these studies.…”

Section: Spectral Distortion and Pulse Broadening Observation As A Fumentioning

confidence: 97%

Optical biopsy in high-speed handheld miniaturized multifocal multiphoton microscopy

Kim

Yazdanfar

et al. 2005

SPIE Proceedings

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Histological analysis is the clinical standard for assessing tissue health and the identification of pathological states. Its invasive nature dictates that its use should be minimized without compromising diagnostic accuracy. A promising method for minimally invasive histological analysis is optical biopsy, which provides cross sectional or 3D images without any physical sectionings. Optical biopsy method based on multiphoton excitation microscopy can image crosssectional image for deep tissue structures with subcellular resolution based on tissue endogenous fluorescence molecules. Despite its suitability for tissue imaging, multiphoton microscopy has not been used for in vivo clinical applications due to both compactness and imaging speed problems. We are developing a high-speed, handheld, miniaturized multifocal multiphoton microscope (H 2 M 4 ) as an optical biopsy probe to enable optical biopsy with subcellular resolution. We incorporate a compact raster scanning actuator based on optimizing a piezo-driven tip tilt mirror by increasing its bandwidth, and reducing its nonlinearity. For flexible light delivery, we choose a photonic bandgap crystal fiber, which transmits ultrashort pulsed laser delivery with reduced spectral distortion and pulse width broadening. We further demonstrate that this fiber produces minimal spatial mode distortion and can achieve comparable image point spread function (PSF) as free space delivery. We further investigate the applicability of multiphoton microscopy for clinical dermal investigation by imaging ex vivo human skins with both normal and abnormal physiologies. This demonstrates the performance of H 2 M 4 and the possibility of optical biopsy for diagnosing skin diseases.

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“…7,8 PCFs can be made with parameters impossible to achieve in standard fibers, which has led some researchers and investigators to suggest that PCFs could become the ultimate transmission waveguide for electromagnetic fields. 9 As long as PCFs fulfill their potentials, they could have important applications in spectroscopy, 10 metrology, 11 biomedicine, 12 imaging, 13 optical coherence tomography (OCT), 14 sensing, [15][16][17][18] and telecommunications. [19][20][21][22][23] On the other hand, although long-period gratings (LPGs) has emerged at the same time as PCFs, 24 the fabrications of PCF-based fiber components have attracted great attention in resent years.…”

Section: Introductionmentioning

confidence: 99%

Long-period gratings in photonic crystal fiber: fabrication, characterization, and potential applications for gas sensing

Zhu

2005

Photonic Crystals and Photonic Crystal Fibers for Sensing Applications

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Although long-period gratings (LPGs) and photonic crystal fibers (PCFs) have emerged at the same time and been around for almost ten years, the fabrications of fiber components in PCFs have attracted great attention in resent years. Post processing of PCFs with a CO 2 laser is very powerful and versatile method for making miniature compact fiberbased devices including LPGs and phase-shifted LPGs. This article will review our research work on fabrication of those gratings in PCFs by use of focused beam from a CO 2 laser and point-by-point writing fashion. Either the mechanical stress relaxation technique or surface deformation method is employed in the design and fabrication of the gratings. The characterizations of the inscribed LPGs in PCFs at high temperature and high strain are also described. The potential applications of PCF-LPG devices for gas sensing have been discussed. Unlike the PCF-based gas sensor that detects the analytes by the interaction of light with gases through the absorption of the evanescent wave in the holes of fiber cladding, the PCF-LPG gas sensing works by the interrogating of the shifts of different resonance wavelength and strength of core-cladding mode coupling in the transmission spectrum. The advantages of the PCF-LPG sensing devices are: (1) high temperature insensitive and stability; (2) compactness when packaged; (3) practical use under hazardous conditions and in high temperature environment.

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Two-photon fluorescence microscope with a hollow-core photonic crystal fiber

Cited by 14 publications

References 14 publications

Ultrafast optical pulse delivery with fibers for nonlinear microscopy

Ultrafast optical pulse delivery with fibers for nonlinear microscopy

Optical biopsy in high-speed handheld miniaturized multifocal multiphoton microscopy

Long-period gratings in photonic crystal fiber: fabrication, characterization, and potential applications for gas sensing

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