Continuous Live-Cell Culture Imaging and Single-Cell Tracking by Computational Lensfree LED Microscopy

Scholz, Gregor; Mariana, Shinta; Dharmawan, Agus Budi; Syamsu, Iqbal; Hörmann, Philipp; Reuse, Carsten; Hartmann, Jana; Hiller, Karsten; Prades, Joan Daniel; Wasisto, Hutomo Suryo; Waag, A.

doi:10.3390/s19051234

Cited by 17 publications

(14 citation statements)

References 24 publications

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“…When comparing our microscope with the existing LHM technologies, it compares favorably in several aspects. For instance, due to its optimized DIHM configuration and optical components, our system experimentally demonstrates higher lateral resolution than most of the reported LHMs [5,14,18,[20][21][22], achieving experimental gain factors of around 2 [5,14,18] or even more [20][21][22]. Only a few contributions reported similar lateral resolutions [12,15].…”

Section: Discussionmentioning

confidence: 71%

“…In particular, lensless holographic microscopes were reported in the past years, providing a successful miniaturized solution for, just to cite some examples, global healthcare monitoring, point-of-care diagnosis, and biomedical applications [4]. As a common point, lensless microscopes are based on costeffective, light-weight, compact, and portable imaging devices that greatly improve rapid and accurate diagnosis in the field-setting [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

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Design, Calibration, and Application of a Robust, Cost-Effective, and High-Resolution Lensless Holographic Microscope

Picazo-Bueno

Trindade

Sanz

et al. 2022

Sensors

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Lensless holographic microscope (LHM) is an emerging very promising technology that provides high-quality imaging and analysis of biological samples without utilizing any lens for imaging. Due to its small size and reduced price, LHM can be a very useful tool for the point-of-care diagnosis of diseases, sperm assessment, or microfluidics, among others, not only employed in advanced laboratories but also in poor and/or remote areas. Recently, several LHMs have been reported in the literature. However, complete characterization of their optical parameters remains not much presented yet. Hence, we present a complete analysis of the performance of a compact, reduced cost, and high-resolution LHM. In particular, optical parameters such as lateral and axial resolutions, lateral magnification, and field of view are discussed into detail, comparing the experimental results with the expected theoretical values for different layout configurations. We use high-resolution amplitude and phase test targets and several microbeads to characterize the proposed microscope. This characterization is used to define a balanced and matched setup showing a good compromise between the involved parameters. Finally, such a microscope is utilized for visualization of static, as well as dynamic biosamples.

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Section: Discussionmentioning

confidence: 71%

Section: Introductionmentioning

confidence: 99%

Design, Calibration, and Application of a Robust, Cost-Effective, and High-Resolution Lensless Holographic Microscope

Picazo-Bueno

Trindade

Sanz

et al. 2022

Sensors

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show abstract

“…Microscale inorganic light-emitting diodes, as a typical inorganic electronic device, show excellent interactions with biological tissues as excitation sources. For example, µ-ILEDs can be an alternative excitation source to an optoelectronic tweezer via noncontact manipulation methods to investigate behaviors of various biological samples such as cells [26][27][28][29][30][31][32], proteins [33], DNA molecules [34,35] and particles [36,37]. In addition to the above applications, µ-ILEDs can also be adopted in optogenetics to control, affect and readout the neural activities of biological creatures, especially for stimulation in brain [38][39][40][41], retina [42][43][44], and audition [45][46][47][48][49].…”

Section: Thermal Analysis Of Fiedsmentioning

confidence: 99%

Recent Advances on Thermal Management of Flexible Inorganic Electronics

Chen

Zhao³

et al. 2020

Micromachines

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Flexible inorganic electronic devices (FIEDs) consisting of functional inorganic components on a soft polymer substrate have enabled many novel applications such as epidermal electronics and wearable electronics, which cannot be realized through conventional rigid electronics. The low thermal dissipation capacity of the soft polymer substrate of FIEDs demands proper thermal management to reduce the undesired thermal influences. The biointegrated applications of FIEDs pose even more stringent requirements on thermal management due to the sensitive nature of biological tissues to temperature. In this review, we take microscale inorganic light-emitting diodes (μ-ILEDs) as an example of functional components to summarize the recent advances on thermal management of FIEDs including thermal analysis, thermo-mechanical analysis and thermal designs of FIEDs with and without biological tissues. These results are very helpful to understand the underlying heat transfer mechanism and provide design guidelines to optimize FIEDs in practical applications.

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“…Besides highly efficient solid-state lighting, ongoing developments of GaN LEDs have driven additional fields of applications, e.g. micro-display [1]- [4] or sensing [5]- [7]. For those purposes, shaping µm-sized emitters with individual control over each pixel is required, most conveniently in a periodic 2D array.…”

Section: Introductionmentioning

confidence: 99%

Processing and Characterization of Monolithic Passive-Matrix GaN-Based MicroLED Arrays With Pixel Sizes From 5 to 50 µm

et al. 2021

Self Cite

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MicroLED arrays with the capability of switching each pixel separately with high frequency can serve as structured micro-illumination light engines for applications in sensing, optogenetics, microscopy and many others. We describe a scalable chip process chain for the fabrication of passive-matrix microLED arrays, which were integrated with PCB-based driving electronics. The arrays were produced by deep-etching of conventional planar LED structures on sapphire, followed by filling and planarization steps. The pixel resolution lies in the range of 254 to 2540 pixelsper-inch (ppi), the arrays consist of 32 x 32 pixels. Optical output powers up to 50 µW per pixel were measured. In comparison to CMOS-based approaches, the presented technology is a simplified strategy to produce microLED arrays with high pixel counts.

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Continuous Live-Cell Culture Imaging and Single-Cell Tracking by Computational Lensfree LED Microscopy

Cited by 17 publications

References 24 publications

Design, Calibration, and Application of a Robust, Cost-Effective, and High-Resolution Lensless Holographic Microscope

Design, Calibration, and Application of a Robust, Cost-Effective, and High-Resolution Lensless Holographic Microscope

Recent Advances on Thermal Management of Flexible Inorganic Electronics

Processing and Characterization of Monolithic Passive-Matrix GaN-Based MicroLED Arrays With Pixel Sizes From 5 to 50 µm

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