Color and monochrome lensless on-chip imaging of Caenorhabditis elegans over a wide field-of-view

Isikman, Serhan O.; Şencan, İkbal; Mudanyali, Onur; Bishara, Waheb; Oztoprak, Cetin; Özcan, Aydogan

doi:10.1039/c001200a

Cited by 53 publications

(63 citation statements)

References 15 publications

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“…The pixel size limited resolution restricts the applications for only telemedicine and for resource limited setting. The so called pixel-super resolution approaches are possible solutions to increase the resolution [16][17][18]. The development in the manufacturing of sensors with smaller pixel size will further extend it applications fields.…”

Section: Resultsmentioning

confidence: 99%

“…This requires a microscope objective and mechanical alignment components. The group of Aydogan Ozcan proposed a new lensless digital holographic microscope which is capable of imaging samples with a field of view corresponding to the entire sensor active area with a resolution in the order of the pixel size of the sensor [1], [14][15][16][17][18].The main key concepts of this setup in contrast to the well-known lensless systems are the use of an LED with a pinhole of size ~ 50-100 µm as point source to achieve a high throughput and the placing of the sensor chip closer to the sample.…”

Section: Introductionmentioning

confidence: 99%

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Quantitative phase imaging by wide field lensless digital holographic microscope

et al. 2015

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Wide field, lensless microscopes have been developed for telemedicine and for resource limited setting [1]. They are based on in-line digital holography which is capable to provide amplitude and phase information resulting from numerical reconstruction. The phase information enables achieving axial resolution in the nanometer range. Hence, such microscopes provide a powerful tool to determine three-dimensional topologies of microstructures.In this contribution, a compact, low-cost, wide field, lensless microscope is presented, which is capable of providing topological profiles of microstructures in transparent material. Our setup consist only of two main components: a CMOSsensor chip and a laser diode without any need of a pinhole. We use this very simple setup to record holograms of microobjects. A wide field of view of ~24 mm², and a lateral resolution of ~2 µm are achieved. Moreover, amplitude and phase information are obtained from the numerical reconstruction of the holograms using a phase retrieval algorithm together with the angular spectrum propagation method. Topographic information of highly transparent micro-objects is obtained from the phase data. We evaluate our system by recording holograms of lines with different depths written by a focused laser beam. A reliable characterization of laser written microstructures is crucial for their functionality. Our results show that this system is valuable for determination of topological profiles of microstructures in transparent material.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Quantitative phase imaging by wide field lensless digital holographic microscope

et al. 2015

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“…This technique has been successfully applied to image eukaryote cells with dimensions ranging from 10 µm (with blood cell, red blood cell, platelet, etc. [3]) to 500 µm (C. elegans [4]). Prokaryote cells, e.g.…”

Section: Introductionmentioning

confidence: 99%

“…Compared to long-established microscopy techniques, lensless imaging [1][2][3][4] combines the advantage of imaging a ultralarge FOV ranging from mm 2 to cm 2 and allowing embedded portable system with low power consumption. This technique has been successfully applied to image eukaryote cells with dimensions ranging from 10 µm (with blood cell, red blood cell, platelet, etc.…”

Section: Introductionmentioning

confidence: 99%

Thin wetting film lensless imaging

et al. 2011

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Lensless imaging has recently attracted a lot of attention as a compact, easy-to-use method to image or detect biological objects like cells, but failed at detecting micron size objects like bacteria that often do not scatter enough light. In order to detect single bacterium, we have developed a method based on a thin wetting film that produces a micro-lens effect. Compared with previously reported results, a large improvement in signal to noise ratio is obtained due to the presence of a micro-lens on top of each bacterium. In these conditions, standard CMOS sensors are able to detect single bacterium, e.g. E.coli, Bacillus subtilis and Bacillus thuringiensis, with a large signal to noise ratio. This paper presents our sensor optimization to enhance the SNR; improve the detection of sub-micron objects; and increase the imaging FOV, from 4.3 mm 2 to 12 mm 2 to 24 mm 2 , which allows the detection of bacteria contained in 0.5µl to 4µl to 10µl, respectively.

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“…Additionally, color has a psychological effect as cytotechnologists and physicians are trained to observe samples in color. Previous methods to render a color image in holographic imaging (lensfree or lens-based) result in aberrated images that exhibit a 'rainbow' like color noise [28]- [30]. These previous approaches captured three high-resolution holograms each taken by a different illumination wavelength [typically red, green and blue (RGB)], and super-imposing them into a final RGB image, which exhibited rainbow like color artifacts that are spatially super-imposed on the object features.…”

Section: Introductionmentioning

confidence: 99%

Field-portable lensfree holographic color microscope for telemedicine applications

Greenbaum

Akbari

Feizi

et al. 2013

2013 IEEE Global Humanitarian Technology Conference (GHTC)

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We report a field-portable lensfree on-chip holographic microscope that can image confluent color samples, with sub-micron resolution over a wide field-of-view (FOV) of ~ 20 mm 2 . This color microscope is suitable for field use as it weighs less than 150 grams and its dimensions are smaller than 17×6×5 cm 3 . The unique design of this lensfree microscope utilizes three computational methods, namely: (i) pixel superresolution to achieve sub-micron resolution with unit magnification over a large FOV, (ii) multi-height phase-recovery that enables imaging of confluent samples, and (iii) YUV color space averaging that mitigates 'rainbow' like color artifacts, typically observed in holographic imaging. To demonstrate the performance of our computational color microscope, we imaged a 1951 USAF test chart and Papanicolaou (Pap) smear samples. This holographic color microscope with its light-weight, costeffective design, and wide FOV could be useful for tele-pathology applications including for example diagnosis of cervical cancer or malaria.

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Color and monochrome lensless on-chip imaging of Caenorhabditis elegans over a wide field-of-view

Cited by 53 publications

References 15 publications

Quantitative phase imaging by wide field lensless digital holographic microscope

Quantitative phase imaging by wide field lensless digital holographic microscope

Thin wetting film lensless imaging

Field-portable lensfree holographic color microscope for telemedicine applications

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