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Literature DB >> 29359107

FIMic: design for ultimate 3D-integral microscopy of in-vivo biological samples.

G Scrofani¹, J Sola-Pikabea¹, A Llavador¹, E Sanchez-Ortiga¹, J C Barreiro¹, G Saavedra¹, J Garcia-Sucerquia², M Martínez-Corral¹.

Abstract

In this work, Fourier integral microscope (FIMic), an ultimate design of 3D-integral microscopy, is presented. By placing a multiplexing microlens array at the aperture stop of the microscope objective of the host microscope, FIMic shows extended depth of field and enhanced lateral resolution in comparison with regular integral microscopy. As FIMic directly produces a set of orthographic views of the 3D-micrometer-sized sample, it is suitable for real-time imaging. Following regular integral-imaging reconstruction algorithms, a 2.75-fold enhanced depth of field and [Formula: see text]-time better spatial resolution in comparison with conventional integral microscopy is reported. Our claims are supported by theoretical analysis and experimental images of a resolution test target, cotton fibers, and in-vivo 3D-imaging of biological specimens.

Keywords: (100.6890) Three-dimensional image processing; (110.6880) Three-dimensional image acquisition; (180.6900) Three-dimensional microscopy

Year: 2017 PMID： 29359107 PMCID： PMC5772586 DOI： 10.1364/BOE.9.000335

Source DB: PubMed Journal: Biomed Opt Express ISSN： 2156-7085 Impact factor: 3.732

17 in total

FIMic: design for ultimate 3D-integral microscopy of in-vivo biological samples.

1. Three-dimensional integral imaging of micro-objects.

2. Camera array based light field microscopy.

3. Resolution enhancement in integral microscopy by physical interpolation.

4. Three-dimensional volumetric object reconstruction using computational integral imaging.

5. Real-time digital holographic microscopy using the graphic processing unit.

6. Wave optics theory and 3-D deconvolution for the light field microscope.

7. Resolution-enhancement for an orthographic-view image display in an integral imaging microscope system.

8. Light field endoscopy and its parametric description.

9. Light field otoscope design for 3D in vivo imaging of the middle ear.

10. Three-dimensional integral imaging and object detection using long-wave infrared imaging.

1. Snapshot projection optical tomography.

2. High-resolution Fourier light-field microscopy for volumetric multi-color live-cell imaging.

3. Fourier light-field microscopy.

4. Fourier light-field imaging of human organoids with a hybrid point-spread function.

5. Robust Depth Estimation for Light Field Microscopy.

6. wFLFM: enhancing the resolution of Fourier light-field microscopy using a hybrid wide-field image.

7. Handheld and Cost-Effective Fourier Lightfield Microscope.

8. Machine Learning-Based View Synthesis in Fourier Lightfield Microscopy.

9. Large Depth-of-Field Integral Microscopy by Use of a Liquid Lens.

10. Miniscope3D: optimized single-shot miniature 3D fluorescence microscopy.