Моделирование движения биологических микрообъектов
в световых пучках
Скиданов Р.В., Рыков М.А.
Аннотация:
Разработан метод расчета сил и моментов сил, действующих на биологические микрообъекты в световых пучках с заданным амплитудно-фазовым распределением. Рассмотрены эксперименты по оптическому захвату клеток дрожжей, и проведено сравнение сил, рассчитанных по экспериментальным данным с силами, полученными в модели. Показано качественное соотношение данных моделирования и натурного эксперимента.
Abstract:
The method of calculation of forces and the moments of the forces operating on biological micro-objects in light beams with set amplitude and phase distribution is developed. Experiments on optical capture of yeast cells are considered and is spent comparison of forces calculated on experimental data with forces received in model is spent. The qualitative parity of the data of modeling and natural experiment is shown.
Ключевые слова
:
оптический захват, биологический микрообъект, геометрическая оптика.
Key words:
optical capture, biological microobject, geometrical optics.
Литература:
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- Ashkin, A. Optical trapping and manipulation of viruses and bacteria / A. Ashkin, J. M. Dziedzic // Science. – 1987. – N 235. – P. 1517-1520.
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- Leitz, G. Stress response in caenorhabditis elegans caused by optical tweezers: wavelength, power, and time dependence / G. Leitz, E. Fallman, S. Tuck, O. Axner // Biophysical Journal. – 2002. – N 82. – P. 2224-22231.
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- Creely, C.M. Raman imaging of floating cells / C.M. Creely [and other] // Optics Express. – 2005. – N 13. – P. 6105-6110.
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- Rappaz, Benjamin Comparative study of human erythrocytes by digital holographic microscopy, confocal microscopy, and impedance volume analyzer / Benjamin Rappaz [et al] // Cytometry Part A. – 2008. – N 73A(10). – P. 895-903.
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- Baskurt, Oguz K. Photometric measurements of red blood cell aggregation: light transmission versus light reflectance / Oguz K. Baskurt [et al] // Journal of Biomedical Optics. – 2009. – N 14(5). – P. 17-23.
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