Abstract
.Significance: Optical trapping is a technique capable of applying minute forces that has been applied to studies spanning single molecules up to microorganisms.Aim: The goal of this perspective is to highlight some of the main advances in the last decade in this field that are pertinent for a biomedical audience.Approach: First, the direct determination of forces in optical tweezers and the combination of optical and acoustic traps, which allows studies across different length scales, are discussed. Then, a review of the progress made in the direct trapping of both single-molecules, and even single-viruses, and single cells with optical forces is outlined. Lastly, future directions for this methodology in biophotonics are discussed.Results: In the 21st century, optical manipulation has expanded its unique capabilities, enabling not only a more detailed study of single molecules and single cells but also of more complex living systems, giving us further insights into important biological activities.Conclusions: Optical forces have played a large role in the biomedical landscape leading to exceptional new biological breakthroughs. The continuous advances in the world of optical trapping will certainly lead to further exploitation, including exciting in-vivo experiments.
Highlights
Half of the Nobel Prize in Physics in 2018 was awarded to Arthur Ashkin for the groundbreaking invention of optical tweezers
Armstrong et al.[16] combined the use of a position-sensitive detector (PSD) with the use of position-sensitive masked detection (PSMD), selectively reflecting light in different directions using an appropriately defined mask, to perform full three-dimensional (3D) direct optical force measurements of trapped single Escherichia coli (E. coli) cells
The study of single molecules is an area that has seen the successful application of optical manipulation for a long time
Summary
In the 21st century, optical manipulation has expanded its unique capabilities, enabling a more detailed study of single molecules and single cells and of more complex living systems, giving us further insights into important biological activities
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