Optical Forces: From Fundamental to Biological Applications

Xin, Hongbao; Li, Yuchao; Liu, Yongchun; Zhang, Yao; Xiao, Yun‐Feng; Li, Baojun

doi:10.1002/adma.202001994

Cited by 126 publications

(69 citation statements)

References 224 publications

(309 reference statements)

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“…18,232 Later on, optical tweezers were applied to study a series of single molecule protein, nucleic acid, and enzymes and provide an important and fine tool in the single molecule arsenal. 17,233,234 There are a series of review articles on high-resolution optical tweezers and single molecule biophysics. Although the single beam optical tweezers have great contributions in biology studies, especially single molecule biophysics, 234 the complex manipulation of the biological cells is in high demand.…”

Section: (B)mentioning

confidence: 99%

“…17,233,234 There are a series of review articles on high-resolution optical tweezers and single molecule biophysics. Although the single beam optical tweezers have great contributions in biology studies, especially single molecule biophysics, 234 the complex manipulation of the biological cells is in high demand. Here, we only focus on the application of structured light in optical tweezers, which also covers a broad area in biomedical applications of optical tweezers.…”

Section: (B)mentioning

confidence: 99%

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Optical trapping with structured light: a review

et al. 2021

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Optical trapping describes the interaction between light and matter to manipulate micro-objects through momentum transfer. In the case of 3D trapping with a single beam, this is termed optical tweezers. Optical tweezers are a powerful and noninvasive tool for manipulating small objects, and have become indispensable in many fields, including physics, biology, soft condensed matter, among others. In the early days, optical trapping was typically accomplished with a single Gaussian beam. In recent years, we have witnessed rapid progress in the use of structured light beams with customized phase, amplitude, and polarization in optical trapping. Unusual beam properties, such as phase singularities on-axis and propagation invariant nature, have opened up novel capabilities to the study of micromanipulation in liquid, air, and vacuum. We summarize the recent advances in the field of optical trapping using structured light beams.

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Section: (B)mentioning

confidence: 99%

Section: (B)mentioning

confidence: 99%

Optical trapping with structured light: a review

et al. 2021

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“…[ 67 ] More detailed discussion about the advances in optical manipulation of biomolecules can be found in recently published review articles. [ 68,69 ] Metallic nanoparticles such as gold nanosphere [ 70 ] (Figure 3b) and nanorod [ 71 ] (Figure 3c) utilize localized surface plasmon resonance (LSPR) to detect viruses. LSPR arises from the collective oscillations of free electrons in nanoparticles with size comparable to the exciting wavelength.…”

Section: Flow‐free Optical Detectionmentioning

confidence: 99%

On‐Chip Optical Detection of Viruses: A Review

Shi

Liu

et al. 2021

Advanced Photonics Research

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The current outbreak of the coronavirus disease‐19 (COVID‐19) pandemic worldwide has caused millions of fatalities and imposed a severe impact on our daily lives. Thus, the global healthcare system urgently calls for rapid, affordable, and reliable detection toolkits. Although the gold‐standard nucleic acid amplification tests have been widely accepted and utilized, they are time‐consuming and labor‐intensive, which exceedingly hinder the mass detection in low‐income populations, especially in developing countries. Recently, due to the blooming development of photonics, various optical chips have been developed to detect single viruses with the advantages of fast, label‐free, affordable, and point of care deployment. Herein, optical approaches especially in three perspectives, e.g., flow‐free optical methods, optofluidics, and surface‐modification‐assisted approaches, are summarized. The future development of on‐chip optical‐detection methods in the wave of emerging new ideas in nanophotonics is also briefly discussed.

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“…Two kinds of optothermal induced thermodynamic phenomena, convective flow and thermophoresis, were excited for biomolecular enrichment and sensing. The two phenomena have greatly facilitated optical force induced tweezers 54 because of their abilities of long-range manipulation and facile energy-efficient trapping of small particles in recent years. [55][56][57] Working principle The interaction between antibody and antigen is a complex and dynamic phenomenon based on noncovalent forces.…”

Section: Wavelength Based Surface Plasmon Resonance Imaging (Wspri)mentioning

confidence: 99%

Optothermophoretic flipping method for biomolecule interaction enhancement in biosensing

Chen

Zeng

Zhou

et al. 2021

Preprint

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The widely used surface-based biomolecule sensing scheme has greatly facilitated the investigation of protein-protein interactions in lab-on-a-chip microfluidic systems. However, in most biosensing schemes, the interactions are driven in a passive way: The overall sensing time and sensitivity are totally dependent on the Brownian diffusion process, which has greatly hindered their efficiency, especially at low concentration level or single-molecule analysis. To break this limitation, we developed an all-optical active method termed optothermophoretic flipping (OTF). The biomolecules were first enriched to aggregation and then pushed to their counterparts for effective contact via a flipped thermophoresis. As a proof-of-concept experiment, we tested its performance via antibody-antigen binding on a surface plasmon resonance imaging (SPRi) platform. We achieved 36.9-fold sensitivity enhancement in this first temporal modulated approach that manipulates biomolecules for interaction enhancement. This method promises to be widely adopted in various biosensing platforms that require ultrasensitivity in colloidal sciences and biochemical studies.

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Optical Forces: From Fundamental to Biological Applications

Cited by 126 publications

References 224 publications

Optical trapping with structured light: a review

Optical trapping with structured light: a review

On‐Chip Optical Detection of Viruses: A Review

Optothermophoretic flipping method for biomolecule interaction enhancement in biosensing

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