Guidestar-free image-guided wavefront shaping

Optical imaging through scattering media is a fundamental challenge in many applications. Recently, breakthroughs such as imaging through biological tissues and looking around corners have been obtained via wavefront-shaping approaches. However, these require an implanted guidestar for determining the wavefront correction, controlled coherent illumination, and most often raster scanning of the shaped focus. Alternative novel computational approaches that exploit speckle correlations avoid guidestars and wavefront control but are limited to small two-dimensional objects contained within the “memory-effect” correlation range. Here, we present a new concept, image-guided wavefront shaping, allowing widefield noninvasive, guidestar-free, incoherent imaging through highly scattering layers, without illumination control. The wavefront correction is found even for objects that are larger than the memory-effect range, by blindly optimizing image quality metrics. We demonstrate imaging of extended objects through highly scattering layers and multicore fibers, paving the way for noninvasive imaging in various applications, from microscopy to endoscopy.

Download Full-text

Fast 3D movement of a laser focusing spot behind scattering media by utilizing optical memory effect and optical conjugate planes

Scientific Reports ◽

10.1038/s41598-019-56214-3 ◽

2019 ◽

Vol 9 (1) ◽

Author(s):

Vinh Tran ◽

Sujit K. Sahoo ◽

Cuong Dang

Keyword(s):

Memory Effect ◽

Light Propagation ◽

Optical Memory ◽

Biological Tissues ◽

Frame Rate ◽

Optimization Process ◽

Turbid Media ◽

Scattering Media ◽

Focus Spot ◽

Wavefront Shaping

AbstractControlling light propagation intentionally through turbid media such as ground glass or biological tissue has been demonstrated for many useful applications. Due to random scattering effect, one of the important goals is to draw a desired shape behind turbid media with a swift and precise method. Feedback wavefront shaping method which is known as a very effective approach to focus the light, is restricted by slow optimization process for obtaining multiple spots. Here we propose a technique to implement feedback wavefront shaping with optical memory effect and optical 4f system to speedy move focus spot and form shapes in 3D space behind scattering media. Starting with only one optimization process to achieve a focusing spot, the advantages of the optical configuration and full digital control allow us to move the focus spot with high quality at the speed of SLM frame rate. Multiple focusing spots can be achieved simultaneously by combining multiple phase patterns on a single SLM. By inheriting the phase patterns in the initial focusing process, we can enhance the intensity of the focusing spot at the edge of memory effect in with 50% reduction in optimization time. With a new focusing spot, we have two partially overlapped memory effect regions, expanding our 3D scanning range. With fast wavefront shaping devices, our proposed technique could potentially find appealing applications with biological tissues.

Download Full-text

Численное моделирование миграции фотонов в однородных и неоднородных цилиндрических фантомах

Журнал технической физики ◽

10.21883/os.2020.06.49417.33-20 ◽

2020 ◽

Vol 128 (6) ◽

pp. 832

Author(s):

А.Ю. Потлов ◽

С.В. Фролов ◽

С.Г. Проскурин

Keyword(s):

Radiation Transfer ◽

Biological Tissues ◽

Photon Density ◽

Radiation Transfer Equation ◽

Scattering Media ◽

Soft Biological Tissues ◽

Photon Diffusion ◽

Low Coherence ◽

The Brain ◽

Pulsed Irradiation

The specific features of photon diffusion of low-coherence pulsed irradiation in phantoms of soft biological tissues (blood-saturated tissues of the brain, breast, etc.) are described. The results of photon migration simulation using the Diffusion Approximation to the Radiation Transfer Equation (RTE) are compared with ones of the Monte Carlo simulations. It has been confirmed that the Photon Density Normalized Maximum (PDNM) moves towards the center of the investigated object in case of relatively uniform and strongly scattering media. In the presence of inhomogeneities, type of the PDNM motion changes drastically. Presence of an absorbing inhomogeneity in the medium directs trajectory of the PDNM motion of towards the point symmetric to the inhomogeneity relative to the geometric center of the investigated object. In case of scattering the PDNM moves toward the direction of the center of the scattering inhomogeneity.

Download Full-text

Detailed study on ill-conditioned transmission matrices when focusing light through scattering media based on wavefront shaping

Applied Physics B ◽

10.1007/s00340-020-07518-0 ◽

2020 ◽

Vol 126 (10) ◽

Author(s):

Longjie Fang ◽

Haoyi Zuo ◽

Menghan Wang ◽

Sijia Chen

Keyword(s):

Scattering Media ◽

Wavefront Shaping

Download Full-text

High-speed single-shot optical focusing through dynamic scattering media with full-phase wavefront shaping

Applied Physics Letters ◽

10.1063/1.5009113 ◽

2017 ◽

Vol 111 (22) ◽

pp. 221109 ◽

Cited By ~ 4

Author(s):

Ashton S. Hemphill ◽

Yuecheng Shen ◽

Yan Liu ◽

Lihong V. Wang

Keyword(s):

High Speed ◽

Single Shot ◽

Scattering Media ◽

Wavefront Shaping ◽

Optical Focusing ◽

Dynamic Scattering

Download Full-text

Cross-sectional imaging through scattering media by quantum-mimetic optical coherence tomography with wavefront shaping

Journal of Optics ◽

10.1088/2040-8986/abc8df ◽

2020 ◽

Vol 23 (1) ◽

pp. 015301

Author(s):

Tomohiro Shirai ◽

Ari T Friberg

Keyword(s):

Optical Coherence Tomography ◽

Optical Coherence ◽

Scattering Media ◽

Cross Sectional ◽

Cross Sectional Imaging ◽

Wavefront Shaping ◽

Sectional Imaging

Download Full-text

A Robust Method for Adjustment of Laser Speckle Contrast Imaging during Transcranial Mouse Brain Visualization

Photonics ◽

10.3390/photonics6030080 ◽

2019 ◽

Vol 6 (3) ◽

pp. 80 ◽

Cited By ~ 5

Author(s):

Vyacheslav Kalchenko ◽

Anton Sdobnov ◽

Igor Meglinski ◽

Yuri Kuznetsov ◽

Guillaume Molodij ◽

...

Keyword(s):

Biological Tissues ◽

Laser Speckle ◽

Robust Method ◽

Scattering Media ◽

Contrast Imaging ◽

Speckle Contrast ◽

Non Invasive ◽

Sagittal Sinus ◽

Brain Vasculature

Laser speckle imaging (LSI) is a well-known and useful approach for the non-invasive visualization of flows and microcirculation localized in turbid scattering media, including biological tissues (such as brain vasculature, skin capillaries etc.). Despite an extensive use of LSI for brain imaging, the LSI technique has several critical limitations. One of them is associated with inability to resolve a functionality of vessels. This limitation also leads to the systematic error in the quantitative interpretation of values of speckle contrast obtained for different vessel types, such as sagittal sinus, arteries, and veins. Here, utilizing a combined use of LSI and fluorescent intravital microscopy (FIM), we present a simple and robust method to overcome the limitations mentioned above for the LSI approach. The proposed technique provides more relevant, abundant, and valuable information regarding perfusion rate ration between different types of vessels that makes this method highly useful for in vivo brain surgical operations.

Download Full-text