On-chip differential interference contrast microscopy using lensless digital holography

Oh, Chulwoo; Isikman, Serhan O.; Khademhosseinieh, Bahar; Özcan, Aydogan

doi:10.1364/oe.18.004717

Cited by 78 publications

(97 citation statements)

References 21 publications

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“…[1][2][3][4]6,7 Recent results confirmed the promising potential of lensfree in-line holography especially for high-throughput cytometry applications. 6 Quite recently, lensfree on-chip imaging has also been extended to fluorescence microscopy to achieve an ultrawide imaging field-of-view ͑FOV͒ of Ͼ8 cm 2 without the use of any lenses or mechanical scanning.…”

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confidence: 73%

“…[1][2][3][4][5][6][7][8] Such on-chip microscope designs would especially benefit microfluidic systems to create powerful capabilities especially for medical diagnostics and cytometry applications. Being light-weight and compact, lensfree imaging can also potentially create an important alternative to conventional lens-based microscopy especially for telemedicine applications.…”

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confidence: 99%

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Lensfree on-chip imaging using nanostructured surfaces

Khademhosseinieh

Şencan

Biener

et al. 2010

Applied Physics Letters

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We introduce the use of nanostructured surfaces for lensfree on-chip microscopy. In this incoherent on-chip imaging modality, the object of interest is directly positioned onto a nanostructured thin metallic film, where the emitted light from the object plane, after being modulated by the nanostructures, diffracts over a short distance to be sampled by a detector-array without the use of any lenses. The detected far-field diffraction pattern then permits rapid reconstruction of the object distribution on the chip at the subpixel level using a compressive sampling algorithm. This imaging modality based on nanostructured substrates could especially be useful to create lensfree fluorescent microscopes on a compact chip.

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mentioning

confidence: 73%

mentioning

confidence: 99%

Lensfree on-chip imaging using nanostructured surfaces

Khademhosseinieh

Şencan

Biener

et al. 2010

Applied Physics Letters

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“…1(a)] and is applicable whenever the wave field of the objects can be considered only as a perturbation of the reference; that is, sparse, slightly scattering objects are to be recorded [16,18]. Using such an architecture, even lensless DHM systems become realizable [19,20].…”

Section: Introductionmentioning

confidence: 99%

“…Special fiber-coupled lasers provide the illumination and guarantee the even spherical reference wave field in this device [7]. In contrast to other DHM approaches, the objects spread all over a substantial volume and do not concentrate in a thin layer [11,12,20]. Therefore, their diffractions can considerably overlap not only at the hologram recording but also at the reconstruction plane.…”

Section: Introductionmentioning

confidence: 99%

In-line hologram segmentation for volumetric samples

et al. 2012

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We propose a fast, noniterative method to segment an in-line hologram of a volumetric sample into in-line subholograms according to its constituent objects. In contrast to the phase retrieval or twin image elimination algorithms, we do not aim or require to reconstruct the complex wave field of all the objects, which would be a more complex task, but only provide a good estimate about the contribution of the particular objects to the original hologram quickly. The introduced hologram segmentation algorithm exploits the special inner structure of the in-line holograms and applies only the estimated supports and reconstruction distances of the corresponding objects as parameters. The performance of the proposed method is demonstrated and analyzed experimentally both on synthetic and measured holograms. We discussed how the proposed algorithm can be efficiently applied for object reconstruction and phase retrieval tasks.

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“…Some DHM setups employ microscope objectives to form the image of the object (Ferraro et al, 2003;Mann et al, 2005;. However, it is also possible to implement DHM in a lensless setup, where the light field scattered from the object is used instead of its projected image (Wagner et al, 1999;Schnars-Juptner, 2002;Repetto et al, 2004;Cruz et al, 2008;Oh et al, 2010). A conventional setup in DHM is based on the use of an external reference wave (RW), which interferes with the field generated by the object, forming an intensity pattern which is known as hologram of the field (Takeda et al, 1982;Kreis, 1986;Yamaguchi-Zhang, 1997;Yamaguchi et al, 2001;Arrizón-Sanchez, 2004;Liebling, 2004;Quian, 2006;Meneses-Fabian, 2006;Guo, 2007;Cruz et al, 2009).…”

Section: Introductionmentioning

confidence: 99%