Compact and portable low-coherence interferometer with off-axis geometry for quantitative phase microscopy and nanoscopy

Girshovitz, Pinhas; Shaked, Natan T.

doi:10.1364/oe.21.005701

Cited by 156 publications

(121 citation statements)

References 26 publications

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“…One of the beams is filtered by pinhole P and reflected by mirror M, where the pinhole transfers only a very small bandwidth around the zero spatial frequency, and thus creates a reference beam by effectively erasing the sample information. 6,7 Next, the reference beam is optically Fourier transformed back to the camera plane by lens L2, where lenses L1 and L2 are positioned in a 4f lens configuration (i.e., the distance between the image plane in the output of the imaging system and L1 is equal to the lens focal length, the distance between L1 and L2 is equal to sum of their focal lengths, and the distance between lens L2 and the camera sensor is equal to the focal length of L2). The second beam that propagates from BS1 is split again by beam splitter BS2, and both sample beams are reflected by two retro-reflectors, RR1 and RR2, …”

Section: Methodsmentioning

confidence: 99%

“…[1][2][3][4][5][6][7] Although it is easier to obtain interference with a highly coherent source, using such a source in interferometric and holographic imaging in general, and in IPM in particular, significantly reduces the image quality due to parasitic interferences and coherent noise. [7][8][9][10][11][12] To overcome this problem, low-coherence light sources are employed. However, to obtain interference using these sources, meticulous alignment between the optical paths of the two beams is required.…”

Section: Introductionmentioning

confidence: 99%

“…20 This feature has been used in the past for other applications, which include solving the phase unwrapping problem, 9,21 recording ultrafast events using suitable temporal encoding, [22][23][24] and obtaining super-resolution capabilities by synthetically increasing the numerical aperture (NA) of the imaging system. [25][26][27] Although the IDIA principle can be implemented in various holographic and interferometric imaging systems, we implemented this technique by modifying the compact and portable interferometric module recently developed in our group, 6,7 which can be connected directly to the digital camera to turn it into a powerful off-axis interferometric camera with a wider FOV.…”

Section: Introductionmentioning

confidence: 99%

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Doubling the field of view in off-axis low-coherence interferometric imaging

2014

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We present a new interferometric and holographic approach, named interferometry with doubled imaging area (IDIA), with which it is possible to double the camera field of view while performing off-axis interferometric imaging, without changing the imaging parameters, such as the magnification and the resolution. This technique enables quantitative amplitude and phase imaging of wider samples without reducing the acquisition frame rate due to scanning. The method is implemented using a compact interferometric module that connects to a regular digital camera, and is useful in a wide range of applications in which neither the field of view nor the acquisition rate can be compromised. Specifically, the IDIA principle allows doubling the off-axis interferometric field of view, which might be narrower than the camera field of view due to low-coherence illumination. We demonstrate the proposed technique for scan-free quantitative optical thickness imaging of microscopic biological samples, including live neurons and a human sperm cell in rapid motion under high magnification. In addition, we used the IDIA principle to perform non-destructive profilometry during a rapid lithography process of transparent structures.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Doubling the field of view in off-axis low-coherence interferometric imaging

2014

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“…These modules, such as the TAU interferometer [29], are capable of adapting existing microscopes for use as holographic microscopes.…”

Section: Compact Interferometric Modules (Cim)mentioning

confidence: 99%

“…The unit itself is a small box and contains very few optical elements, making production of this unit very cost-effective [29].…”

Section: Compact Interferometric Modules (Cim)mentioning

confidence: 99%

Label-Free Quantitative Imaging of Sperm for In-Vitro Fertilization Using Interferometric Phase MicroscopyIVF, IMSI, ICSI, IPM, Holography, Imaging, Sperm

Mirsky¹,

Barnea²,

Shaked³

2016

JFIV Reprod Med Genet

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Accurate morphological evaluation via imaging of sperm cells is a critical step in both routine sperm analysis and sperm cell selection for in vitro fertilization. In this paper, we review the significant advantages of interferometric phase microscopy (IPM), also called digital holographic microscopy, for label-free sperm imaging in fertility clinics. We first review the current state of the art of label-free sperm cell imaging for in vitro fertilization, including brightfield, Zernike phase contrast, differential interference contrast (DIC), Hoffman modulation contrast and polarized light microscopy, as well as intracytoplasmic morphologically selected sperm injection (IMSI). Using experimental demonstrations, we compare the limitations of these techniques for label-free sperm imaging. IPM and its advantages are then discussed in detail. These include the ability to receive quantitative data regarding the 3D structure of sperm cells, as well as data concerning sperm biomass and morphology without labeling. The current gap to clinical use is discussed, as well as the possible solution of employing compact and simple holographic modules, which may allow holographic imaging to reach the clinic in the near future.

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