Prêmio Nobel de Física: O que são pinças ópticas?
Keywords:
Arthur Ashkin, Pinças Ópticas, Física BiológicaAbstract
On October 2, 2018, the Royal Swedish Academy of Sciences announced the Nobel Prize in Physics winners. Among the winners was the American Arthur Ashkin, 96, for his contribution to the invention of optical tweezers and applications in biological sciences. But what are op- tical tweezers? In this review paper we will describe how this technique works, its principles, applications and future perspectives.
References
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2. ASHKIN A. Optical trapping and manipulation of neutral particles using lasers. P. Natl. Acad. Sci. 1997; 94: 4853 – 4860.
3. NEUMAN KC, BLOCK M. Optical trapping. Rev. Sci. Instrum. 2004; 75: 2787 – 2809.
4. GRIER DG. A revolution in optical manipulation. Nature. 2003; 424: 810 – 816.
5. STELLAMANNS Eea. Optical trapping reveals propulsion forces, power generation and motility eciency of the unicellular parasites Trypanosoma brucei bricei. Sci Rep. 2014; 4: 6515 – 6520.
6. SCHWINGE MBM. Force Mapping during the Formation and Maturation of Cell Adhesion Sites with Multiple Optical Tweezers. Plos One. 2013; 8: 1 – 12.
7. REBANE AA, MA L, ZHANG Y. Structure-Based Derivation of Protein Folding Intermediates and Energies from Optical Tweezers. Biophys J. 2016; 110: 441 – 456.
8. GALLA Lea. Hydrodynamic Slip on DNA Observed by Optical Tweezers-Controlled Translocation Experiments with Solid- State and Lipid-Coated Nanopores. Nano Lett. 2014; 14: 4176 – 4182.
9. STEVENSON DJD, GUNN-MOORE F, DHOLAKIA K. Light forces the pace: optical manipulation for biophotonics. J of Biomed Opt. 2010.; 15: 041503 – 041521.
10. BAUMANN Gea. Stretching of single collapsed dna molecules. Biophysical Journal. 2000.; 78: 1965 – 1978.
11. BAZONI RFea. Force-dependent persistence length of DNA intercalator complexes measured in single molecule stretching experiments.. Soft Matter. 2015; 4: 1000 – 1039.
12. Y.MURAYAMA , WADA H, SANO N. Dynamic force spectroscopy of a single condensed DNA. Europhysics Letters. 2007;: 1902 – 191079.
13. ALVES PS. Teoria e Calibração de Pinça Óptica. Viçosa- MG: Dissertação (Mestrado em Física) — Universidade Federal de Viçosa.; 2012.
14. ROOSEN G. he resistance against the movement of a rigour sphere in viscous fluids, which is embedded between two parallel layered barries. Annals. Physics. ; 10: 89-119.
15. VIANA NB. Pinças ópticas e aplicações Belos Horizonte- MG: Tese (Doutorado ) — Universidade Federal de Minas Gerais; 2012.
16. VLADESCU IDea. Quantifying force-dependent and zero force DNA intercalation by single - molecule stretching. Nature Methods. 2007; 4: 577 – 522.
17. ROCHA MS. Extracting physical chemistry from mechanics: a new approach to investigate DNA interactions with drugs and proteins in single molecule experiments. Integrative Biology. 2015;: 976-986.
18. LIMA CHM“. Estudo da Interação do Intercalante Doxorrubicina em Condensados de DNA Via Espectroscopia de Força Viçosa-MG: Tese (Doutorado em Física) — Universidade Federal de Viçosa; 2018.
19. TATIANE SVPea. Anomalous diffusion and q-Weibull velocity distributions in epithelial cell migration. PLoS One. 2017; 12: 1 – 19.
20. PONTES Bea. Structure and elastic properties of tunneling nanotubes. European Biophysics Journal. 2008; 14: 121 – 129.
21. PONTES A. Quantum dots in biomedical research, biomedical engineering technical applications in Medicine. InTech. 2012; 12: 976 – 986.
22. MAZOLLI A, MAIA NETO PA, NUSSENZVEIG HM. A revolution in optical manipulation. Nature. 2003;: 3021 – 3041.
23. BROWNE WR, FERINGA BL. Making molecular machines work.. Nature Nanotechnology. 2006; 1: 25 – 35.
24. JONES Pea. Rotation detection in light-driven nanorotors. ACS Nano. 2009;: 3077 – 3084.
25. SINCLAIR Gea. Assembly of 3 dimensional structures using programmable holographic optical tweezers. Optics Express. 2004; 12: 5475 – 5480.
26. A.MARTÍNEZ I, ROLDÁN E, RICA RA. Colloidal heat engines: a review. Soft Matter. 2017; 110: 22 – 36.
2. ASHKIN A. Optical trapping and manipulation of neutral particles using lasers. P. Natl. Acad. Sci. 1997; 94: 4853 – 4860.
3. NEUMAN KC, BLOCK M. Optical trapping. Rev. Sci. Instrum. 2004; 75: 2787 – 2809.
4. GRIER DG. A revolution in optical manipulation. Nature. 2003; 424: 810 – 816.
5. STELLAMANNS Eea. Optical trapping reveals propulsion forces, power generation and motility eciency of the unicellular parasites Trypanosoma brucei bricei. Sci Rep. 2014; 4: 6515 – 6520.
6. SCHWINGE MBM. Force Mapping during the Formation and Maturation of Cell Adhesion Sites with Multiple Optical Tweezers. Plos One. 2013; 8: 1 – 12.
7. REBANE AA, MA L, ZHANG Y. Structure-Based Derivation of Protein Folding Intermediates and Energies from Optical Tweezers. Biophys J. 2016; 110: 441 – 456.
8. GALLA Lea. Hydrodynamic Slip on DNA Observed by Optical Tweezers-Controlled Translocation Experiments with Solid- State and Lipid-Coated Nanopores. Nano Lett. 2014; 14: 4176 – 4182.
9. STEVENSON DJD, GUNN-MOORE F, DHOLAKIA K. Light forces the pace: optical manipulation for biophotonics. J of Biomed Opt. 2010.; 15: 041503 – 041521.
10. BAUMANN Gea. Stretching of single collapsed dna molecules. Biophysical Journal. 2000.; 78: 1965 – 1978.
11. BAZONI RFea. Force-dependent persistence length of DNA intercalator complexes measured in single molecule stretching experiments.. Soft Matter. 2015; 4: 1000 – 1039.
12. Y.MURAYAMA , WADA H, SANO N. Dynamic force spectroscopy of a single condensed DNA. Europhysics Letters. 2007;: 1902 – 191079.
13. ALVES PS. Teoria e Calibração de Pinça Óptica. Viçosa- MG: Dissertação (Mestrado em Física) — Universidade Federal de Viçosa.; 2012.
14. ROOSEN G. he resistance against the movement of a rigour sphere in viscous fluids, which is embedded between two parallel layered barries. Annals. Physics. ; 10: 89-119.
15. VIANA NB. Pinças ópticas e aplicações Belos Horizonte- MG: Tese (Doutorado ) — Universidade Federal de Minas Gerais; 2012.
16. VLADESCU IDea. Quantifying force-dependent and zero force DNA intercalation by single - molecule stretching. Nature Methods. 2007; 4: 577 – 522.
17. ROCHA MS. Extracting physical chemistry from mechanics: a new approach to investigate DNA interactions with drugs and proteins in single molecule experiments. Integrative Biology. 2015;: 976-986.
18. LIMA CHM“. Estudo da Interação do Intercalante Doxorrubicina em Condensados de DNA Via Espectroscopia de Força Viçosa-MG: Tese (Doutorado em Física) — Universidade Federal de Viçosa; 2018.
19. TATIANE SVPea. Anomalous diffusion and q-Weibull velocity distributions in epithelial cell migration. PLoS One. 2017; 12: 1 – 19.
20. PONTES Bea. Structure and elastic properties of tunneling nanotubes. European Biophysics Journal. 2008; 14: 121 – 129.
21. PONTES A. Quantum dots in biomedical research, biomedical engineering technical applications in Medicine. InTech. 2012; 12: 976 – 986.
22. MAZOLLI A, MAIA NETO PA, NUSSENZVEIG HM. A revolution in optical manipulation. Nature. 2003;: 3021 – 3041.
23. BROWNE WR, FERINGA BL. Making molecular machines work.. Nature Nanotechnology. 2006; 1: 25 – 35.
24. JONES Pea. Rotation detection in light-driven nanorotors. ACS Nano. 2009;: 3077 – 3084.
25. SINCLAIR Gea. Assembly of 3 dimensional structures using programmable holographic optical tweezers. Optics Express. 2004; 12: 5475 – 5480.
26. A.MARTÍNEZ I, ROLDÁN E, RICA RA. Colloidal heat engines: a review. Soft Matter. 2017; 110: 22 – 36.
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Published
2020-06-03
How to Cite
Henrique Moreira Lima, C. (2020). Prêmio Nobel de Física: O que são pinças ópticas?. South American Journal of Basic Education, Technical and Technological, 7(1), 78–93. Retrieved from https://periodicos.ufac.br/index.php/SAJEBTT/article/view/3264
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Artigos Originais Ciências Exatas e da Terra
