Deep‐Ultraviolet Biomolecular Imaging and Analysis

Kumamoto, Yoshiaki; Taguchi, Akihito; Kawata, Satoshi

doi:10.1002/adom.201801099

Cited by 39 publications

(34 citation statements)

References 214 publications

(238 reference statements)

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“…These results nd application in improving the performance of ZMWs for single molecule analysis at high concentrations, and are especially relevant for monitoring fast biomolecular dynamics, 4,5 realizing ultrafast single-photon sources, 14 and for interrogating molecules with ultraviolet plasmonics. [57][58][59][60][61][62] Methods…”

Section: Discussionmentioning

confidence: 99%

“…Achieving the brightest emission rate together with short uorescence lifetimes is important for applications on fast biomolecular dynamics, 4,5 single-photon sources, 14 and also for the newly-developing eld of ultraviolet plasmonics. [57][58][59][60][61][62] Here we rationally explore the use of rectangular-shaped nanoapertures milled in aluminum to enhance the uorescence emission rate of single molecules from the near infrared (excitation 635 nm, detection 655 to 755 nm) down to the deep ultraviolet (excitation 266 nm, detection 310 to 410 nm). We use aluminum layers with optimized deposition parameters, 63,64 as the response for gold lms falls below 600 nm and hence gold lms cannot be used efficiently for dyes with emission from the green to the ultraviolet.…”

Section: Introductionmentioning

confidence: 99%

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Zero-mode waveguides can be made better: fluorescence enhancement with rectangular aluminum nanoapertures from the visible to the deep ultraviolet

et al. 2020

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Zero-mode waveguides can be made better: fluorescence enhancement with rectangular aluminum nanoapertures from the visible to the deep ultraviolet

et al. 2020

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“…This fluorescence emission is mainly due to the autofluorescence of tryptophan. 22,26,27 The contrast variations observed on the fluorescence images do not seem specific to tryptophan because they are observed on the other images, particularly with the bandpass at 412-438 nm and 420-480 nm. The best contrast is observed for Figure 2f at 275/420-480 nm which suggests that some muscle fibres are more fluorescent than others.…”

Section: Muscle Fibre Fluorescencementioning

confidence: 87%

“…The best contrast is observed for Figure 2f at 275/420-480 nm which suggests that some muscle fibres are more fluorescent than others. The other fluorophores most likely to be involved in the autofluorescence of UV-excited muscle fibres are NADH (260 and 345/400-600 nm) 15,[27][28][29] and pyridoxine (252 and 322/400-550 nm). 15 Their excitation is lower at 275 nm.…”

Section: Muscle Fibre Fluorescencementioning

confidence: 99%

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Preferred metabolic pathway of bovine muscle fibre revealed by synchrotron–deep ultraviolet fluorescence imaging

Astruc

Loison

Jamme

et al. 2019

J. Spectral Imaging

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The different bovine muscle fibre types I, IIA and IIX are characterised by their preferred metabolic pathway, either oxidative (I, IIA) or glycolytic (IIX), and their contraction speed, either slow-twitch (I) or fast-twitch (IIA, IIX). These physiological specificities are associated with variations in intracellular composition and their fluorescence spectra signatures. We hypothesised that these slight differences in autofluorescence responses could be used to discriminate the muscle fibre types by fluorescence imaging. Serial histological cross-sections of beef longissimus dorsi were performed: the start set was used to identify the metabolic and contractile type of muscle fibres by both immunohistoenzymology and immunohistofluorescence, and the following set was used to acquire synchrotron–deep ultraviolet (UV) autofluorescence images after excitation in the UV range (275 nm and 315 nm). This strategy made it possible to explore the label-free autofluorescence of muscle cells previously subtyped by histochemistry. Glycolytic cells (IIX) showed more intense fluorescence than oxidative cells (I and IIA) with near-90 % accuracy. This discrimination is more specifically assigned to the fluorescence of nicotinamide adenine dinucleotide. UV autofluorescence was unable to discriminate contractile type.

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Recent Progress of Flexible Image Sensors for Biomedical Applications

2021

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irradiating X-rays, have become indispensable approaches for diagnosing diseases. [4] Other similar applications may include imaging based on positron emission tomography using gamma rays, [10] deep ultraviolet resonant Raman imaging of a cell, [11] histopathology images using visible light, [12] and electroencephalography through nearinfrared (NIR) light [13] (Figure 1).An image sensor, or an imager, is an essential electronic device that supports such type of bioimaging technology. Image sensors have two main components: single or multiple optical sensors (for detecting light) and circuits (for reading the output from optical sensors). Multiple optical sensors are arranged in an array with specific rows and columns. By reading light signals from the sensors using readout circuits, the spatial and/or temporal distribution-localization of biological information is determined, while its dynamics can be analyzed as an image. Two important applications of such bioimaging techniques are static imaging, which involves techniques, such as X-ray and CT, and dynamic imaging, which concerns object detection such as pulse, [14] blood oxygen levels, [15,16] and blood flow. [17] In static imaging, the imaging speed is not required as only little dynamic movements exist, but it requires high resolution and high sensitivity. Meanwhile, in dynamic imaging, high resolution is not required, but high-speed imaging is essential (Figure 2).Recently, the miniaturization of semiconductor devices has led to the development of imaging devices for wearable electronics. As a typical example, a smartwatch integrates small optical sensors that can continuously monitor biological information, such as pulse, blood pressure, and blood oxygen levels, for the long-term by simply wearing the sensors in direct contact with the skin.The flexibility of image sensors is improving to reduce the discomfort caused by such wearable electronics. Because hard and heavy devices cause relatively high discomfort, their prolonged and continuous use increases the psychological and physical burden on the user. Thus, a flexible imaging device that uses soft materials and thin substrates to reduce the device thickness and weight is an effective approach for load reduction. Further, flexible devices are easier to bend and attach to the bioplane than traditional solid devices. Consequently, problems of inaccuracy or intermittency of data acquisition caused by fluctuations in the physical distance between the target skin surface and the device can be reduced. Therefore, flexible imaging Flexible image sensors have attracted increasing attention as new imaging devices owing to their lightness, softness, and bendability. Since light can measure inside information from outside of the body, optical-imaging-based approaches, such as X-rays, are widely used for disease diagnosis in hospitals. Unlike conventional sensors, flexible image sensors are soft and can be directly attached to a curved surface, such as the skin, for continuous measurement of biometric information wi...

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Deep‐Ultraviolet Biomolecular Imaging and Analysis

Cited by 39 publications

References 214 publications

Zero-mode waveguides can be made better: fluorescence enhancement with rectangular aluminum nanoapertures from the visible to the deep ultraviolet

Zero-mode waveguides can be made better: fluorescence enhancement with rectangular aluminum nanoapertures from the visible to the deep ultraviolet

Preferred metabolic pathway of bovine muscle fibre revealed by synchrotron–deep ultraviolet fluorescence imaging

Recent Progress of Flexible Image Sensors for Biomedical Applications

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