Digital holography as a method for 3D imaging and estimating the biovolume of motile cells

Merola, Francesco; Miccio, Lisa; Memmolo, Pasquale; Caprio, Giuseppe Di; Galli, Andrea; Puglisi, Roberto; Balduzzi, Donatella; Coppola, Giuseppe; Netti, Paolo A.; Ferraro, Pietro

doi:10.1039/c3lc50515d

Cited by 145 publications

(100 citation statements)

References 38 publications

(40 reference statements)

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“…Their system utilizes optical tweezers to trap and rotate the cells as they flow through a microchannel, enabling holographic imaging of the sperm from multiple angles and the production of a tomographic 3D model. Aside from enabling highthroughput, imaging the live sperm in a microchannel allows the sperm to retain its natural shape, as opposed to the altered shapes produced when sperm adheres to a slide or is crushed under a coverslip [26,28].…”

Section: Novel Clinical Applicationsmentioning

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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Section: Novel Clinical Applicationsmentioning

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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“…Interdependency of phase-map extraction with optical thickness and hence computation of RI of the RBC is customarily done by using two suspension media of known RI. Procedures to decouple these entangled parameters is elucidated elsewhere [31,34,35,[39][40][41]43].…”

Section: Theoretical Consideration Of Phase Extractionmentioning

confidence: 99%

“…But in DHR, RBCs are made stationary by adhering them directly to a glass surface that can invoke perturbations from two facets -physical contact and their own weight which might alter their innate morphology. Digital holography in conjugation with OTs (HOT) has been reported for 3D shape evaluation of convex shape objects by observing cells along different directions [39][40][41][42]. Mohanty et al [43] have combined HOTs with quantitative phasemicroscopy for decoupling geometric thickness from RI.…”

Section: Introductionmentioning

confidence: 99%

Role of Arbitrary Intensity Profile Laser Beam in Trapping of RBC for Phase-imaging

Kumar

Srivastava

Mehta

et al. 2016

Journal of the Optical Society of Korea

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Red blood cells (RBCs) are customarily adhered to a bio-functionalised substrate to make them stationary in interferometric phase-imaging modalities. This can make them susceptible to receive alterations in innate morphology due to their own weight. Optical tweezers (OTs) often driven by Gaussian profile of a laser beam is an alternative modality to overcome contact-induced perturbation but at the same time a steeply focused laser beam might cause photo-damage. In order to address both the photo-damage and substrate adherence induced perturbations, we were motivated to stabilize the RBC in OTs by utilizing a laser beam of 'arbitrary intensity profile' generated by a source having cavity imperfections per se. Thus the immobilized RBC was investigated for phase-imaging with sinusoidal interferograms generated by a compact and robust Michelson interferometer which was designed from a cubic beam splitter having one surface coated with reflective material and another adjacent coplanar surface aligned against a mirror. Reflected interferograms from bilayers membrane of a trapped RBC were recorded and analyzed. Our phase-imaging set-up is limited to work in reflection configuration only because of the availability of an upright microscope. Due to RBC's membrane being poorly reflective for visible wavelengths, quantitative information in the signal is weak and therefore, the quality of experimental results is limited in comparison to results obtained in transmission mode by various holographic techniques reported elsewhere.

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“…Although this method was first described some twenty years ago [8], computing power has recently developed to the stage that DIHM can be routinely implemented in desktop machines. There are two distinct implementations of this method: a quantitative phase contrast method to assess the axial thickness of microscopic subjects [9,10,11]; and a method for three-dimensional localisation and imaging of objects [12,13,14,15]. This paper concentrates on the latter, and its application to microbial pathogens.…”

Section: Introductionmentioning

confidence: 99%

Investigating the Swimming of Microbial Pathogens Using Digital Holography

Findlay

Walrad

Wilson

2016

Biophysics of Infection

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Digital holography as a method for 3D imaging and estimating the biovolume of motile cells

Cited by 145 publications

References 38 publications

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

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

Role of Arbitrary Intensity Profile Laser Beam in Trapping of RBC for Phase-imaging

Investigating the Swimming of Microbial Pathogens Using Digital Holography

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