Label-free 3D computational imaging of spermatozoon locomotion, head spin and flagellum beating over a large volume

Daloğlu, Mustafa; Luo, Wei; Shabbir, Faizan; Lin, Francis; Kim, Kevin; Lee, Inje; Jiang, Jiaqi; Cai, Wen-Jun; Ramesh, Vishwajith; Yu, Meng-Yuan; Ozcan, Aydogan

doi:10.1038/lsa.2017.121

Cited by 53 publications

(69 citation statements)

References 59 publications

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“…In the last couple of years, several studies aimed at tracking the location of the entire flagellum in 3-D space and time (13)(14)(15). Silva-Villalobos et al (13) used an oscillating objective mounted in a bright-field optical microscope, covering a 16 µm depth at a rate of 5000 images per second, where the best flagellum focused sub-regions were associated to their respective z positions.…”

Section: Introductionmentioning

confidence: 99%

High-resolution 4-D acquisition of freely swimming human sperm cells without staining

et al. 2020

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We present a new acquisition method that enables high-resolution, fine-detail full reconstruction of the three-dimensional movement and structure of individual human sperm cells swimming freely. We achieve both retrieval of the three-dimensional refractive-index profile of the sperm head, revealing its fine internal organelles and time-varying orientation, and the detailed fourdimensional localization of the thin, highly-dynamic flagellum of the sperm cell. Live human sperm cells were acquired during free swim using a high-speed off-axis holographic system that does not require any moving elements or cell staining. The reconstruction is based solely on the natural movement of the sperm cell and a novel set of algorithms, enabling the detailed fourdimensional recovery. Using this refractive-index imaging approach, we believe we have detected an area in the cell that is attributed to the centriole. This method has great potential for both biological assays and clinical use of intact sperm cells.

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Section: Introductionmentioning

confidence: 99%

High-resolution 4-D acquisition of freely swimming human sperm cells without staining

et al. 2020

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“…We have demonstrated the applicability of our technique for a label-free 3D reconstruction of human sperm's flagellar beat with unprecedented tempo-spatial precision. Common methods to characterize 3D flagellar beating of mammalian sperm involved combinations of light microscopy with a piezo-driven objective or digital holographic microscopy (DHM), also known as holographic phase retrieval 30,[37][38][39][40][41] . The piezo-driven method allows to acquire at Additionally, acquisition of planes takes place at different time points, requiring high-speed high-sensitivity cameras recording 5,000 images s -1 , that are very expensive and thus, restrict the availability of this technique to only few labs 41 .…”

Section: Discussionmentioning

confidence: 99%

Multifocal imaging for precise, label-free tracking of fast biological processes in 3D

Hansen

Gong

Wachten

et al. 2020

Preprint

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Many biological processes happen on a nano-to millimeter scale and within milliseconds.Established methods such as confocal microscopy are suitable for precise 3D recordings but lack the temporal or spatial resolution to resolve fast 3D processes and require labeled samples.Multifocal imaging (MFI) allows high-speed 3D imaging but suffers from the compromise between spatial resolution and field-of-view (FOV), requiring bright fluorescent labels and limiting its application. Here, we present a new approach for high-resolution, label-free, highspeed MFI, based on dark-field microscopy and operative over large volumes. We introduce a 3D reconstruction algorithm that increases resolution and depth of the sampled volume without compromising speed and FOV. This allowed us to characterize the flagellar beat of human sperm and surrounding fluid flow with a precision below the Abbe limit, in a large volume, and at high speed. Our MFI concept is cost-effective, can be easily built, and does not rely on object labeling, making it broadly applicable.

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“…Whilst also of pertinence to a broad biological community, we anticipate that the data generated in this study (available as described in the accompanying data access statement) will also be of intense interest to the biophysical modelling community. Datasets generated with the same level of flagellar detail and scale have, to the best of our knowledge, been previously unavailable, with more of the distal flagellar tip being captured here than has been realised on large scales prior to this study, with the notable exception of the recent work of Daloglu et al [16] that applied sophisticated holographic imaging to capture beats in three dimensions. Easily-obtainable waveform data with the level of fidelity presented in this study has the potential to further the vast research area of heterogeneous population modelling, allowing the emergence of the next generation of evidence-based biophysical modelling for cell populations, spermatozoan behaviours in complex microenvironments, and more generally active matter physics.…”

Section: Discussionmentioning

confidence: 99%

“…A recent tool has been developed for this purpose with phase contrast microscopy by Gallagher et al [14], though it is limited due to its current inability to capture the distal region of the flagellum, despite the reported importance of the distal flagellum in motility mechanics [15]. Other recent works have similarly developed techniques to capture the beating flagellum, including the distal region, most notably the three-dimensional capture of the flagellar waveform achieved by Daloglu et al [16] with holographic imaging. However, compared to phase contrast microscopy, this is a highly-specialist imaging modality requiring custom circuitry together with sophisticated hardware and processing, whilst the former is already ubiquitous in theriogenology and andrology facilities [6,9], and also in the study of a wealth of eukaryotic monoflagellates [17].…”

Section: Introductionmentioning

confidence: 99%

Computer-assisted beat-pattern analysis and the flagellar waveforms of bovine spermatozoa

Walker

Phuyal

Ishimoto

et al. 2020

Preprint

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Plagued by hurdles in information extraction, handling, and processing, computer-assisted sperm analysis (CASA) systems have typically neglected the complex flagellar waveforms of spermatozoa, despite their defining role in cell motility. Recent developments in imaging techniques and data processing have produced significantly-improved methods of waveform digitisation. Here, we utilise these improvements to demonstrate that near-complete flagellar capture is realisable on the scale of hundreds of cells, and, further, that meaningful statistical comparisons of flagellar waveforms may be readily performed with widely-available tools. Representing the advent of high-fidelity computer-assisted beat-pattern analysis (CABA), we show how such a statistical approach can distinguish between samples using complex flagellar beating patterns rather than crude summary statistics. Dimensionality-reduction techniques applied to entire samples also reveal qualitatively-distinct components of the beat, and a novel data-driven methodology for the generation of representative synthetic waveform data is proposed.

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Label-free 3D computational imaging of spermatozoon locomotion, head spin and flagellum beating over a large volume

Cited by 53 publications

References 59 publications

High-resolution 4-D acquisition of freely swimming human sperm cells without staining

High-resolution 4-D acquisition of freely swimming human sperm cells without staining

Multifocal imaging for precise, label-free tracking of fast biological processes in 3D

Computer-assisted beat-pattern analysis and the flagellar waveforms of bovine spermatozoa

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