The single‐cell screening has attracted great attentions in advanced biomedicine and tissue biology, especially for the early disease diagnosis and treatment monitoring. In this work, by using a specific‐designed fiber probe with a flat facet, we propose an “optical fan” strategy to screen K562 cells at the single‐cell level from a populations of RBCs. After the 980‐nm laser beam injected into the fiber probe, the RBCs were blown away but holding target K562 cells in place. Further, multiple leukemic cells can be screened from hundreds of red blood cells, providing an efficient approach for the cell screening. The experimental results were interpreted by the numerical simulation, and the stiffness of optical fan was also discussed. 相似文献
Successful therapy of twin‐to‐twin transfusion syndrome requires accurate imaging to guide laser photocoagulation of the anastomosing placental vessels. Photoacoustic (PA) imaging is an alternative imaging method that provides contrast for hemoglobin, and in this study, it was used to visualize chorionic superficial and subsurface vasculature in human placentas. The strong potential of PA imaging to guide minimally invasive fetal therapies was demonstrated. Further details can be found in the article by Efthymios Maneas, Rosalind Aughwane, Nam Huynh, et al. ( e201900167 ).
If gold nanorods are used as photoabsorbers, then light in the near infrared tissue window can generate a strong photothermal effect. In this issue, C. Paviolo et al. show that near infrared light can be used to evoke a calcium response in neuronal cells treated with gold nanorods. This suggests new opportunities for peripheral nerve regeneration and infrared neural stimulation. (Picture: C. Paviolo et al., pp. 761–765 in this issue) 相似文献
A false‐colored and merged image of fresh, ex vivo rat kidney acquired using an excitation‐scanning hyperspectral imaging system. The spectral image was acquired using excitation wavelengths from 360 to 550 nm. Colors represent principal components extracted from a spectral image cube featuring no added labels or markers. Further details can be found in the article by Peter F. Favreau, Joshua A. Deal, Bradley Harris, et al. ( e201900183 ).
This study proposed a Sparse‐Graph Manifold Learning (SGML) method to balance the sparseness and morphology preserving for bioluminescence tomography reconstruction. It inherits the benefits of non‐convex sparsity constraint and dynamic Laplacian graph model. The results of numerical simulations and in vivo experiments demonstrate that the proposed method yields accurate and robust results in terms of tumor spatial location and morphology recovery. Further details can be found in the article by Hongbo Guo, Ling Gao, Jingjing Yu, et al. ( e201960218 )
A new quantitative phase imaging (QPI) modality, coined multi‐ATOM, can now capture and process enormous amount of quantitative phase single‐cell images (>700,000 cells) at a ultrahigh throughput without compromising sub‐cellular resolution. It could empower label‐free single‐cell analysis where large‐scale and cost‐effective screening is necessary. Further details can be found in the article by Kelvin C. M. Lee, Andy K. S. Lau, Anson H. L. Tang, et al. ( e201800479 ).
A novel capsule optoacoustic endoscopy (COE) system is built which provides high‐quality 360‐degree images of the entire lumen, specifically designed for typical dimensions of human esophagus. The pill‐shaped encapsulated probe consists of a novel and highly sensitive ultrasound transducer fitted with an integrated miniature pre‐amplifier. For the first time, ex vivo volumetric vascular network images to a depth of 2 mm in swine esophageal lining using COE are demonstrated. Further details can be found in the article by Hailong He, Antonios Stylogiannis, Parastoo Afshari, et al. ( e201800439 )
An ultrafast time‐stretch imaging technique for edge detection is demonstrated. The edge detection based on the optical directional derivative is realized by using differential detection. Since the edge detection is implemented in the physical layer, the computation complexity in the back‐end digital signal processing is very low. The blood red cells and cancer cells can be easily identified by distinguishing the edges. Further details can be found in the article by Bo Dai, LuHe, Lulu Zheng, Yongfeng Fu et al. ( e201800044 ).
Hyperspectral imaging microscopy of rat lung cryoslices can be used to identify individual pulmonary microvascular endothelial cells (PMVECs) in the presence of a high lung autofluorescence of the same peak fluorescence emission wavelength. PMVECs expressing green fluorescent protein are shown in green, lung autofluorescence is shown in red, and nuclei are shown in blue. A plot of the spectral library used for linear unmixing is also shown. (Picture: S. Leavesley et al., pp. 67–84 in this issue) 相似文献
Raman spectroscopy has been used in this study to obtain biochemical fingerprint patterns of collagen fibers in native aortic heart valve tissues. Using this non‐contact screening tool, we were able to monitor the increasing damage of collagen fibers due to enzymatic treatment or cryopreservation. (Picture: M. Votteler et al., pp. 47–56 in this issue) 相似文献
A 3D printed stereotaxic head mount that enables high resolution imaging of the anterior chamber of the eye in alert and freely mobile mice is designed in this study. The system is placed non‐invasively using temporal mount bars and a snout mount, without breaking the skin or risking suffocation, while an endoscopic channel stabilizes the ocular probes. Further details can be found in the article by Bjorn Paulson, Sangwook Lee, Miyeon Jue, Kyungsung Lee, Sanghwa Lee, Guk Bae Kim, Youngjin Moon, Joo Yong Lee, Namkug Kim, and Jun Ki Kim ( e201960188 ).
Hyperspectral scanning laser optical tomography is developed to provide spectrally resolved volume data sets with high spectral resolution for large mesoscopic samples. It can be used to resolve largely overlapping fluorophores, as demonstrated by the 3D fluorescence hyperspectral reconstruction of a dual‐labelled mouse thymus gland sample and to distinguish between signals from autofluorescence of diseased and normal tissue without prior knowledge. Further details can be found in the article by Lingling Chen, Guiye Li, Li Tang, et al. ( e201800221 ).
A fast polarization‐resolved second harmonic generation microscope is implemented to map collagen orientation in thick and deforming tissues during mechanical assays. This system is based on line‐to‐line switching of the laser polarization using an electro‐optical modulator and works in epi‐detection geometry. After proper calibration, it successfully highlights the collagen dynamic alignment along the traction direction in ex vivo murine skin dermis. Further details can be found in the article by Guillaume Ducourthial, Jean‐Sébastien Affagard, Margaux Schmeltz, et al. ( e201800336 ).
How does the ischemic tissue re‐vascularize? Now we can visualize the reperfusion process at high spatial resolution by using a dual‐wavelength MEMS scanning based optical resolution photoacoustic microscopy (OR‐PAM) system. The fast imaging capability enables continuous monitoring of skin reperfusion in a mouse model. It's also found that the ischemic tissue has a significantly higher oxygen consumption rate in the reperfusion stage comparing to the normal tissue. Further details can be found in the article by Renzhe Bi, U.S. Dinish, Chi Ching Goh, et al. ( e201800454 ).
The role of ultraviolet radiation in oxidative stress‐related ocular pathologies is less known than its role in skin cancer. Excessive exposure to ultraviolet radiation is associated with increased oxidative stress in eye tissues, which may promote the development of photokeratitis, cataract, and retinal damages. Children are especially vulnerable: large pupils, transparent ocular media. Efficient everyday protection of the eye should be considered from early age. (Image: with permission from Carl Zeiss Vision International GmbH, Aalen, Germany) Further details can be found in the article by Iliya V. Ivanov, Timo Mappes, Patrick Schaupp, et al. ( e201700377 ).
A new high‐speed cellular imaging method using clinically applicable moxifloxacin labeling, called as moxifloxacin based confocal microscopy (MBCM), was developed for fast and sensitive tumor detection and delineation. The MBCM demarcated malignant brain tumor from normal brain by visualizing dense and irregular cell distribution in the tumor. An image processing algorithm was developed for automated brain tumor detection. Further details can be found in the article by Seunghun Lee, Won Yeong Park, Hoonchul Chang, et al. ( e201900197 ).
Optoacoustics (OA) is combined with near‐infrared optical tomography (NIROT) in reflection mode to quantitatively image vasculature oxygen saturation (SO2) levels in phantoms containing vessels at depths up to 25 mm. Using NIROT to estimate the light fluence, the OA signals' spectral distortion was reduced from 60–150% to 10–20%. Results suggest that SO2 levels can be determined with <10% error and that temporal changes can be monitored with even better accuracy. Further details can be found in the article by Leonie Ulrich, Linda Ahnen, Hidayet Günhan Akarçay, et al. ( e201800112 ).
Optimized light delivery allows for single shot whole organ optoacoustic imaging. The authors present an optimized illumination concept for volumetric tomography that utilizes 3D printing in combination with custom‐made optical fiber illumination. The new approach showed a clear advantage over conventional, single‐sided illumination strategies by eliminating the need to correct for illumination variances and resulting in enhancement of the effective field of view, greater penetration depth and significant improvements in the overall image quality. Further details can be found in the article by Benedict Mc Larney, Johannes Rebling, Zhenyue Chen, et al. ( e201800387 )
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