Boliang Jia scite author profile

The nanostructures and patterns that exist in nature have inspired researchers to develop revolutionary components for use in modern technologies and our daily lives. The nanoscale imaging of biological samples with sophisticated analytical tools, such as scanning electron microscopy (SEM) and transmission electron microscopy (TEM), has afforded a precise understanding of structures and has helped reveal the mechanisms contributing to the behaviors of the samples but has done so with the loss of photonic properties. Here, we present a new method for printing biocompatible “superlenses” directly on biological objects to observe subdiffraction-limited features under an optical microscope in color. We demonstrate the nanoscale imaging of butterfly wing scales with a super-resolution and larger field-of-view (FOV) than those of previous dielectric microsphere techniques. Our approach creates a fast and flexible path for the direct color observation of nanoscale biological features in the visible range and enables potential optical measurements at the subdiffraction-limited scale.

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Super-Resolution Real Imaging in Microsphere-Assisted Microscopy

Lai

Wang

et al. 2016

PLoS ONE

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Microsphere-assisted microscopy has received a lot of attention recently due to its simplicity and its capability to surpass the diffraction limit. However, to date, sub-diffraction-limit features have only been observed in virtual images formed through the microspheres. We show that it is possible to form real, super-resolution images using high-refractive index microspheres. Also, we report on how changes to a microsphere’s refractive index and size affect image formation and planes. The relationship between the focus position and the additional magnification factor is also investigated using experimental and theoretical methods. We demonstrate that such a real imaging mode, combined with the use of larger microspheres, can enlarge sub-diffraction-limit features up to 10 times that of wide-field microscopy’s magnification with a field-of-view diameter of up to 9 μm.

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Optothermophoretic flipping method for biomolecule interaction enhancement

Chen

Zeng

Zhou

et al. 2022

Biosensors and Bioelectronics

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Passively and actively enhanced surface plasmon resonance sensing strategies towards single molecular detection

et al. 2022

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Real-time red blood cell counting and osmolarity analysis using a photoacoustic-based microfluidic system

Zhao

Wen

et al. 2021

Lab Chip

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Boliang Jia

In situ printing of liquid superlenses for subdiffraction-limited color imaging of nanobiostructures in nature

Super-Resolution Real Imaging in Microsphere-Assisted Microscopy

Optothermophoretic flipping method for biomolecule interaction enhancement

Passively and actively enhanced surface plasmon resonance sensing strategies towards single molecular detection

Real-time red blood cell counting and osmolarity analysis using a photoacoustic-based microfluidic system

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