Shakila Naznin scite author profile

Shakila Naznin

5Publications

44Citation Statements Received

111Citation Statements Given

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214

111

Affiliations

University of Nottingham, Khulna University, Faculty (United Kingdom)

Publications

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Picosecond ultrasonics for elasticity-based imaging and characterization of biological cells

Pérez-Cota

Fuentes-Domínguez

Cavera

et al. 2020

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Characterization of the elasticity of biological cells is growing as a new way to gain insight into cell biology. Cell mechanics are related to most aspects of cellular behavior, and applications in research and medicine are broad. Current methods are often limited since they require physical contact or lack resolution. From the methods available for the characterization of elasticity, those relying on high frequency ultrasound (phonons) are the most promising because they offer label-free, high (even super-optical) resolution and compatibility with conventional optical microscopes. In this Perspective contribution, we review the state of the art of picosecond ultrasonics for cell imaging and characterization, particularly for Brillouin scattering-based methods, offering an opinion for the challenges faced by the technology. The challenges are separated into biocompatibility, acquisition speed, resolution, and data interpretation and are discussed in detail along with new results.

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Super-resolution imaging using nano-bells

Fuentes-Domínguez

Pérez-Cota

Naznin

et al. 2018

Sci Rep

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In this paper we demonstrate a new scheme for optical super-resolution, inspired, in-part, by PALM and STORM. In this scheme each object in the field of view is tagged with a signal that allows them to be detected separately. By doing this we can identify and locate each object separately with significantly higher resolution than the diffraction limit. We demonstrate this by imaging nanoparticles significantly smaller than the optical resolution limit. In this case the “tag” we have used is the frequency of vibration of nanoscale “bells” made of metallic nanoparticles whose acoustic vibrational frequency is in the multi-GHz range. Since the vibration of the particles can be easily excited and detected and the frequency is directly related to the particle size, we can separate the signals from many particles of sufficiently different sizes even though they are smaller than, and separated by less than, the optical resolution limit. Using this scheme we have been able to localise the nanoparticle position with a precision of ~3 nm. This has many potential advantages - such nanoparticles are easily inserted into cells and well tolerated, the particles do not bleach and can be produced easily with very dispersed sizes. We estimate that 50 or more different particles (or frequency channels) can be accessed in each optical point spread function using the vibrational frequencies of gold nanospheres. However, many more channels may be accessed using more complex structures (such as nanorods) and detection techniques (for instance using polarization or wavelength selective detection) opening up this technique as a generalized method of achieving super-optical resolution imaging.

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Apparent attenuation by opto-acoustic defocus in phonon microscopy

et al. 2020

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Polarization-Sensitive Super-Resolution Phononic Reconstruction of Nanostructures

et al. 2022

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In this paper, we show for the first time the polarization-sensitive super-resolution phononic reconstruction of multiple nanostructures in a liquid environment by overcoming the diffraction limit of the optical system (1 μm). By using timeresolved pump−probe spectroscopy, we measure the acoustic signature of nanospheres and nanorods at different polarizations. This enables the size, position, and orientation characterization of multiple nanoparticles in a single point spread function with the precision of 5 nm, 3 nm, and 1.4°, respectively. Unlike electron microscopy where a high vacuum environment is needed for imaging, this technique performs measurements in liquids at ambient pressure, ideal to study the insights of living specimens. This is a potential path toward super-resolution phononic imaging where the acoustic signatures of multiple nanostructures could act as an alternative to fluorescent labels. In this context, phonons also offer the opportunity to extract information about the mechanical properties of the surrounding medium as well as access to subsurface features.

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Characterising the size and shape of metallic nano-structures by their acoustic vibrations

et al. 2020

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Shakila Naznin

Picosecond ultrasonics for elasticity-based imaging and characterization of biological cells

Super-resolution imaging using nano-bells

Apparent attenuation by opto-acoustic defocus in phonon microscopy

Polarization-Sensitive Super-Resolution Phononic Reconstruction of Nanostructures

Characterising the size and shape of metallic nano-structures by their acoustic vibrations

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