Adrian Mariampillai scite author profile

We report on imaging of microcirculation by calculating the speckle variance of optical coherence tomography (OCT) structural images acquired using a Fourier domain mode-locked swept-wavelength laser. The algorithm calculates interframe speckle variance in two-dimensional and three-dimensional OCT data sets and shows little dependence to the Doppler angle ranging from 75 degrees to 90 degrees . We demonstrate in vivo detection of blood flow in vessels as small as 25 microm in diameter in a dorsal skinfold window chamber model with direct comparison with intravital fluorescence confocal microscopy. This technique can visualize vessel-size-dependent vascular shutdown and transient vascular occlusion during Visudyne photodynamic therapy and may provide opportunities for studying therapeutic effects of antivascular treatments without on exogenous contrast agent.

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Blood-vessel closure using photosensitizers engineered for two-photon excitation

Collins

et al. 2008

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The spatial control of optical absorption provided by twophoton excitation (TPE) has led to tremendous advances in microscopy 1 and microfabrication 2 . Medical applications of TPE in photodynamic therapy (PDT) 3,4 have often been suggested 5-18 , but have been made impractical by the low twophoton cross-sections of photosensitiser drugs (i.e. compounds taken up by living tissues that become toxic on absorption of light). The invention of efficient two-photon activated drugs will allow precise manipulation of treatment volumes in three dimensions, to a level unattainable with current techniques. Here we present a new family of PDT drugs designed for efficient TPE, and use one of them to demonstrate selective closure of blood vessels via TPE-PDT in vivo. These conjugated porphyrin dimers have two-photon cross-sections that are more than two orders of magnitude greater than those of clinical photosensitisers 17 . This is the first demonstration of in vivo PDT using a photosensitiser engineered for efficient two-photon excitation.Photodynamic therapy is used to treat diseases characterised by neoplastic growth including various cancers, age-related macular degeneration (AMD) and actinic keratosis 3,4 . Cell death is induced by photoexcitation of a sensitiser, generally via production of singlet oxygen. In the absence of light the photosensitiser is benign, so systemic toxicity is rare and treatment may be repeated without acquired resistance. Two-photon excitation of the photosensitiser should allow greater precision than is attainable by conventional one-photon excitation, as a consequence of the quadratic dependence of TPE on the local light intensity -the amount of TPE is inversely proportional to the fourth power of the distance from the focus. In addition, the longer wavelengths associated with TPE allow treatment deeper into tissue, by minimising absorption from endogenous chromophores.High instantaneous photon densities are essential for two-photon excitation. Early TPE-PDT studies used nanosecond lasers, but the dominant effect was photothermal damage [5][6][7] . The advent of commercial femtosecond tuneable Ti:sapphire lasers has greatly facilitated the investigation of TPE-PDT, and the limiting factor has become the availability of suitable photosensitisers. The majority of chromophores possess low two-photon cross-sections, of the order of 1-100 Goeppert-Mayer units (1 GM = 10 -50 cm 4 s photon -1 ). For example, the two FDA-approved PDT photosensitisers, verteporfin and Photofrin (cross sections 50 GM and 10 GM respectively) 17 , are unlikely to be suitable for TPE-PDT, as the high light intensities needed to achieve a therapeutic effect are close to the thresholds for photothermal or photomechanical damage 18 .Several design strategies for TPE-PDT photosensitisers have been reported recently [11][12][13][14][15][16] , but few of these compounds have yet been studied in vitro 15 , and, to date, none have progressed to in vivo testing. Porphyrin derivatives are often effective PDT agents, as exemplified ...

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Optimized speckle variance OCT imaging of microvasculature

et al. 2010

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We optimize speckle variance optical coherence tomography (svOCT) imaging of microvasculature in high and low bulk tissue motion scenarios. To achieve a significant level of image contrast, frame rates must be optimized such that tissue displacement between frames is less than the beam radius. We demonstrate that higher accuracy estimates of speckle variance can enhance the detection of capillaries. These findings are illustrated in vivo by imaging the dorsal window chamber model (low bulk motion). We also show svOCT imaging of the nonstabilized finger (high bulk motion), using optimized imaging parameters, demonstrating better vessel detection than Doppler OCT.

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Review of speckle and phase variance optical coherence tomography to visualize microvascular networks

et al. 2013

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Abstract. High-resolution mapping of microvasculature has been applied to diverse body systems, including the retinal and choroidal vasculature, cardiac vasculature, the central nervous system, and various tumor models. Many imaging techniques have been developed to address specific research questions, and each has its own merits and drawbacks. Understanding, optimization, and proper implementation of these imaging techniques can significantly improve the data obtained along the spectrum of unique research projects to obtain diagnostic clinical information. We describe the recently developed algorithms and applications of two general classes of microvascular imaging techniques: speckle-variance and phase-variance optical coherence tomography (OCT). We compare and contrast their performance with Doppler OCT and optical microangiography. In addition, we highlight ongoing work in the development of variance-based techniques to further refine the characterization of microvascular networks. © The Authors. Published by SPIE under a Creative Commons Attribution 3.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.

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