Abstract: A method for lens-free imaging of a sample or objects within the sample uses multi-height iterative phase retrieval and rotational field transformations to perform wide FOV imaging of pathology samples with clinically comparable image quality to a benchtop lens-based microscope. The solution of the transport-of-intensity (TIE) equation is used as an initial guess in the phase recovery process to speed the image recovery process. The holographically reconstructed image can be digitally focused at any depth within the object FOV (after image capture) without the need for any focus adjustment, and is also digitally corrected for artifacts arising from uncontrolled tilting and height variations between the sample and sensor planes. In an alternative embodiment, a synthetic aperture approach is used with multi-angle iterative phase retrieval to perform wide FOV imaging of pathology samples and increase the effective numerical aperture of the image.

Abstract: A method for lens-free imaging of a sample or objects within the sample uses multi-height iterative phase retrieval and rotational field transformations to perform wide FOV imaging of pathology samples with clinically comparable image quality to a benchtop lens-based microscope. The solution of the transport-of-intensity (TIE) equation is used as an initial guess in the phase recovery process to speed the image recovery process. The holographically reconstructed image can be digitally focused at any depth within the object FOV (after image capture) without the need for any focus adjustment, and is also digitally corrected for artifacts arising from uncontrolled tilting and height variations between the sample and sensor planes. In an alternative embodiment, a synthetic aperture approach is used with multi-angle iterative phase retrieval to perform wide FOV imaging of pathology samples and increase the effective numerical aperture of the image.

Abstract: Described herein is a bone tissue clearing method with enhanced optical access. Compositions and techniques for bone tissue clearing include continuous convective flow during the clearing process, amino alcohol to minimize tissue autofluorescence, and an imaging procedure that minimizes refractive index variations in light-sheet microscopy. These improvements allowed the Inventors to achieve whole-bone clearing with an imaging depth of up to about 1.5 mm while maintaining fluorescence and a signal-to-noise ratio (SNR) that permits detection and 3D placement of single cells. In various embodiments, the present application teaches methods and kits for clearing and optionally subsequently visualizing tissue containing bone.

Abstract: Described herein is a bone tissue clearing method with enhanced optical access. Compositions and techniques for bone tissue clearing include continuous convective flow during the clearing process, amino alcohol to minimize tissue autofluorescence, and an imaging procedure that minimizes refractive index variations in light-sheet microscopy. These improvements allowed the Inventors to achieve whole-bone clearing with an imaging depth of up to about 1.5 mm while maintaining fluorescence and a signal-to-noise ratio (SNR) that permits detection and 3D placement of single cells. In various embodiments, the present application teaches methods and kits for clearing and optionally subsequently visualizing tissue containing bone.