Prêmio Nobel de Física: O que são pinças ópticas?
Palavras-chave:
Arthur Ashkin, Pinças Ópticas, Física BiológicaResumo
Em 2 de Outubro de 2018, a Real Academia de Ciências da Suécia anunciou os ganhadores do Prêmio Nobel de Física. Dentre os ganhadores, estava o norte-americano Arthur Ashkin, de 96 anos, por sua contribuição na invenção das pinças ópticas e aplicações nas ciências biológicas. Mas o que são as pinças opticas? Neste artigo de revisão descreveremos o funcionamento desta técnica, seus princípios, aplicações e perspectivas futuras.
Referências
1. ASHKIN A. Acceleration and trapping of particles by radiation pressure. Phys. Rev. Lett. 1970;: 1560 – 1572.
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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Publicado
2020-06-03
Como Citar
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. Recuperado de https://periodicos.ufac.br/index.php/SAJEBTT/article/view/3264
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Artigos Originais Ciências Exatas e da Terra
