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Researchers from ����ɫ�� worked with NTU to revolutionise 4D printing by making a 3D fabricated material change its shape and back again repeatedly without electrical components.

The research introduced a semi-automatic computational clinical tool that aims to extract structural information, such as failure load, from radiological scans of patients using functional spinal units.

����ɫ�� research team led by Assoc Prof Dr Ye Ai, in collaboration with Assistant Prof Chrishan Ramachandra from National Heart Centre Singapore (NHCS), developed a sheathless acoustic fluorescence activated cell sorting (aFACS) system for single-cell level fluorescence detection and isolation.

����ɫ�� leads in-depth review on the impending reality of 3D printed organs and analyses recent accomplishments, limitations and opportunities for future research.

����ɫ�� researchers developed a new microfluidic fluorescence-activated droplet sorting system that can isolate single-cell droplets with high accuracy and high yield using a detachable surface acoustic wave transducer.

DUT and ����ɫ�� researchers developed a new strategy that enhances the brightness and clarity of sub-cellular structures when dyed with novel rhodamine fluorophores, laying the ground for the advancement of super-resolution microscopes.

Researchers from DUT and ����ɫ�� developed a new class of quaternary piperazine-substituted rhodamines with outstanding quantum yields (Φ = 0.93) and superior brightness (ε × Φ = 8.1 × 104 L·mol–1·cm–1), for imaging cell membranes and lysosomes in biological cells with super-resolution microscopy.

Recent years have witnessed a rapid evolution of advanced fluorescence imaging techniques, such as single-molecule localization microscopy (SMLM) that allows for unprecedented resolution beyond the Abbe diffraction limit of the optical microscope.

You can find more details at /Research/Research-News/2019/12/Illuminating-the-path-for-super-resolution-imaging

Researchers from ����ɫ�� and DUT have developed a novel strategy for chemists to achieve brighter fluorescence and clearer resolution with the use of a new class of rhodamines.

����ɫ�� together with the University of Miyazaki developed a novel methodology to provide non-invasive analysis of meniscal implants.

����ɫ�� research team led by Associate Prof Dr Ye Ai developed a microfluidic impedance flow cytometry device for the lateral position measurement of single cells and particles with a novel N-shaped electrode design.

The ultrathin films are able to be injected using minimally-invasive syringe needles and can be used as a platform to deliver molecular and cellular drugs.