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Sensitive detection and estimation of particle non-sphericity from the complex Fourier spectrum of its light-scattering profile. / Romanov, Andrey V.; Konokhova, Anastasiya I.; Yastrebova, Ekaterina S. et al.

In: Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 235, 01.09.2019, p. 317-331.

Research output: Contribution to journalArticlepeer-review

Harvard

Romanov, AV, Konokhova, AI, Yastrebova, ES, Gilev, KV, Strokotov, DI, Maltsev, VP & Yurkin, MA 2019, 'Sensitive detection and estimation of particle non-sphericity from the complex Fourier spectrum of its light-scattering profile', Journal of Quantitative Spectroscopy and Radiative Transfer, vol. 235, pp. 317-331. https://doi.org/10.1016/j.jqsrt.2019.07.001

APA

Romanov, A. V., Konokhova, A. I., Yastrebova, E. S., Gilev, K. V., Strokotov, D. I., Maltsev, V. P., & Yurkin, M. A. (2019). Sensitive detection and estimation of particle non-sphericity from the complex Fourier spectrum of its light-scattering profile. Journal of Quantitative Spectroscopy and Radiative Transfer, 235, 317-331. https://doi.org/10.1016/j.jqsrt.2019.07.001

Vancouver

Romanov AV, Konokhova AI, Yastrebova ES, Gilev KV, Strokotov DI, Maltsev VP et al. Sensitive detection and estimation of particle non-sphericity from the complex Fourier spectrum of its light-scattering profile. Journal of Quantitative Spectroscopy and Radiative Transfer. 2019 Sept 1;235:317-331. doi: 10.1016/j.jqsrt.2019.07.001

Author

Romanov, Andrey V. ; Konokhova, Anastasiya I. ; Yastrebova, Ekaterina S. et al. / Sensitive detection and estimation of particle non-sphericity from the complex Fourier spectrum of its light-scattering profile. In: Journal of Quantitative Spectroscopy and Radiative Transfer. 2019 ; Vol. 235. pp. 317-331.

BibTeX

@article{79f2dac6532b45b696d288065265e8fb,
title = "Sensitive detection and estimation of particle non-sphericity from the complex Fourier spectrum of its light-scattering profile",
abstract = "We develop a fast method to estimate the non-sphericity of arbitrary-shaped particles from the complex Fourier spectrum of its light-scattering profile (LSP), measured with the scanning flow cytometer (SFC). We show that previously used amplitude spectrum is not sufficiently sensitive to the non-sphericity and extensively study the phase of the spectral peak for spheroids in the framework of the Rayleigh–Gans–Debye (RGD) approximation. Based on this analysis we construct a new spectral parameter P – the weighted deviation of the complex spectrum around the peak from that for an equivalent sphere determined by the previously published spectral characterization method for spheres (SCMS). We also propose a geometric indicator of non-sphericity η as the relative volume difference from that of the best-fit sphere. These two new parameters apply to particles of arbitrary shape and strongly correlate with each other for rigorously simulated LSPs for spheroids and biconcave disks in a wide range of sizes, refractive indices, and orientations. This correlation is the core of the new method, allowing one to provide both the estimate and the confidence range of η from the experimental value of P. The method is both sensitive and specific to small non-sphericity. For instance, the median error of estimated aspect ratio for simulated LSPs of spheroids is 0.024. We test the resulting algorithm on the real experimental measurements of milk fat globules and red blood cells (RBCs) during the spherization process. These results raise a question about the actual shape of a spherized RBC in the flow inside the SFC. The applicability domain of the method is determined mainly by that of the SCMS and includes biological objects with sizes larger than 7 wavelengths in the liquid host medium. Moreover, we briefly discuss the potential extension of the method to larger refractive indices.",
keywords = "Fourier spectrum, Inverse problem, Light scattering, Non-sphericity, Single-particle characterization, SIZE, SCANNING FLOW-CYTOMETRY, NONSPHERICAL PARTICLES, SHAPE, REFRACTIVE-INDEX, RED-BLOOD-CELLS, TRANSFORM, POLARIZATION",
author = "Romanov, {Andrey V.} and Konokhova, {Anastasiya I.} and Yastrebova, {Ekaterina S.} and Gilev, {Konstantin V.} and Strokotov, {Dmitry I.} and Maltsev, {Valeri P.} and Yurkin, {Maxim A.}",
note = "Publisher Copyright: {\textcopyright} 2019 Elsevier Ltd",
year = "2019",
month = sep,
day = "1",
doi = "10.1016/j.jqsrt.2019.07.001",
language = "English",
volume = "235",
pages = "317--331",
journal = "Journal of Quantitative Spectroscopy and Radiative Transfer",
issn = "0022-4073",
publisher = "Elsevier Ltd",

}

RIS

TY - JOUR

T1 - Sensitive detection and estimation of particle non-sphericity from the complex Fourier spectrum of its light-scattering profile

AU - Romanov, Andrey V.

AU - Konokhova, Anastasiya I.

AU - Yastrebova, Ekaterina S.

AU - Gilev, Konstantin V.

AU - Strokotov, Dmitry I.

AU - Maltsev, Valeri P.

AU - Yurkin, Maxim A.

N1 - Publisher Copyright: © 2019 Elsevier Ltd

PY - 2019/9/1

Y1 - 2019/9/1

N2 - We develop a fast method to estimate the non-sphericity of arbitrary-shaped particles from the complex Fourier spectrum of its light-scattering profile (LSP), measured with the scanning flow cytometer (SFC). We show that previously used amplitude spectrum is not sufficiently sensitive to the non-sphericity and extensively study the phase of the spectral peak for spheroids in the framework of the Rayleigh–Gans–Debye (RGD) approximation. Based on this analysis we construct a new spectral parameter P – the weighted deviation of the complex spectrum around the peak from that for an equivalent sphere determined by the previously published spectral characterization method for spheres (SCMS). We also propose a geometric indicator of non-sphericity η as the relative volume difference from that of the best-fit sphere. These two new parameters apply to particles of arbitrary shape and strongly correlate with each other for rigorously simulated LSPs for spheroids and biconcave disks in a wide range of sizes, refractive indices, and orientations. This correlation is the core of the new method, allowing one to provide both the estimate and the confidence range of η from the experimental value of P. The method is both sensitive and specific to small non-sphericity. For instance, the median error of estimated aspect ratio for simulated LSPs of spheroids is 0.024. We test the resulting algorithm on the real experimental measurements of milk fat globules and red blood cells (RBCs) during the spherization process. These results raise a question about the actual shape of a spherized RBC in the flow inside the SFC. The applicability domain of the method is determined mainly by that of the SCMS and includes biological objects with sizes larger than 7 wavelengths in the liquid host medium. Moreover, we briefly discuss the potential extension of the method to larger refractive indices.

AB - We develop a fast method to estimate the non-sphericity of arbitrary-shaped particles from the complex Fourier spectrum of its light-scattering profile (LSP), measured with the scanning flow cytometer (SFC). We show that previously used amplitude spectrum is not sufficiently sensitive to the non-sphericity and extensively study the phase of the spectral peak for spheroids in the framework of the Rayleigh–Gans–Debye (RGD) approximation. Based on this analysis we construct a new spectral parameter P – the weighted deviation of the complex spectrum around the peak from that for an equivalent sphere determined by the previously published spectral characterization method for spheres (SCMS). We also propose a geometric indicator of non-sphericity η as the relative volume difference from that of the best-fit sphere. These two new parameters apply to particles of arbitrary shape and strongly correlate with each other for rigorously simulated LSPs for spheroids and biconcave disks in a wide range of sizes, refractive indices, and orientations. This correlation is the core of the new method, allowing one to provide both the estimate and the confidence range of η from the experimental value of P. The method is both sensitive and specific to small non-sphericity. For instance, the median error of estimated aspect ratio for simulated LSPs of spheroids is 0.024. We test the resulting algorithm on the real experimental measurements of milk fat globules and red blood cells (RBCs) during the spherization process. These results raise a question about the actual shape of a spherized RBC in the flow inside the SFC. The applicability domain of the method is determined mainly by that of the SCMS and includes biological objects with sizes larger than 7 wavelengths in the liquid host medium. Moreover, we briefly discuss the potential extension of the method to larger refractive indices.

KW - Fourier spectrum

KW - Inverse problem

KW - Light scattering

KW - Non-sphericity

KW - Single-particle characterization

KW - SIZE

KW - SCANNING FLOW-CYTOMETRY

KW - NONSPHERICAL PARTICLES

KW - SHAPE

KW - REFRACTIVE-INDEX

KW - RED-BLOOD-CELLS

KW - TRANSFORM

KW - POLARIZATION

UR - http://www.scopus.com/inward/record.url?scp=85069747645&partnerID=8YFLogxK

U2 - 10.1016/j.jqsrt.2019.07.001

DO - 10.1016/j.jqsrt.2019.07.001

M3 - Article

AN - SCOPUS:85069747645

VL - 235

SP - 317

EP - 331

JO - Journal of Quantitative Spectroscopy and Radiative Transfer

JF - Journal of Quantitative Spectroscopy and Radiative Transfer

SN - 0022-4073

ER -

ID: 21046472