Systematic analysis of frequency dependent differential photoacoustic cross-section data for source size estimation

Kaushik, Anuj; Paul, Ankan; Saha, Ratan K.

doi:10.1364/josaa.409955

Cited by 5 publications

(2 citation statements)

References 25 publications

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“…The standard approach is to iteratively expand Eq. ( 5) to obtain a faithful solution [4,5]. It has been recently shown that an approximate solution can also be obtained by consiedering only the first term of Eq.…”

Section: Theoretical Components and Numerical Implementationmentioning

confidence: 99%

“…Efforts have been made to measure optoacoustic (OA) signals from individual cells in vitro [3]. Several theoretical studies have also been conducted to examine OA emission from normal and pathological cells both in the time and frequency domains [4]. It has been concluded that the OA spectral features depend upon the size and shape of the source and also on the direction of the measurement.…”

Section: Introductionmentioning

confidence: 99%

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Estimation of photoacoustic spectra for normal and pathological red blood cells using a modified Green’s function approach

Saha,

Mandal

2023

Opto-Acoustic Methods and Applications in Biophotonics VI

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The frequency domain optoacoustic (OA) wave equation is inherently inhomogeneous. The first inhomogeneous term arises because of the OA effect (i.e., conversion of optical energy into acoustical energy).The second term appears due to sound-speed mismatch between the source and the ambient medium. The conventional Green's function method works well in absence of the second term (i.e., acoustically homogeneous source). Recently, it has been shown that a modified Green's function (MGF) approach provides faithful solution to the OA wave equation for an acoustically inhomogeneous source. Herein, we employ the MGF technique for accurate estimation of the OA spectra for normal and pathological red blood cells (RBCs). The shapes in 2D mimicking normal RBC, stomatocyte and echinocyte (with six equidistant identical spicules) were simulated (with constant area ≈ 16.5 µm 2 ) and subsequently, the OA spectra were computed over 10-1000 MHz by evaluating the integral equation employing the Monte Carlo integration method. The OA spectrum for an equivalent disc was also calculated for comparison. The sound-speed within the source region was taken as 1639 m/s and that of the surrounding medium was chosen as 1500 m/s. The first minimum of the OA spectra for disc and echinocyte appeared almost at the same location (440 MHz) when probed from an angle, θ=π/4 with respect to the axis of symmetry. The locations for the first minimum became 280 and 390 MHz, respectively for normal RBC and stomatocyte (for θ=π/4). These 0A spectral features may be useful for morphological characterization of normal and deformed RBCs.

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Section: Theoretical Components and Numerical Implementationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Estimation of photoacoustic spectra for normal and pathological red blood cells using a modified Green’s function approach

Saha,

Mandal

2023

Opto-Acoustic Methods and Applications in Biophotonics VI

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Predicting optoacoustic spectral behaviour of human erythrocytes, stomatocytes and echinocytes using a modified Green’s function method

Saha

2022

Eur Biophys J

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Characterization of normal and deformed red blood cells using simulated differential photoacoustic cross-section spectral data

Kaushik¹,

Saha²

2021

J. Phys. Commun.

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Frequency dependent differential photoacoustic cross-section (DPACS) over a large frequency band (100–1000 MHz) has been computed and subsequently, morphological parameters of photoacoustic (PA) source have been quantified. Green’s function method has been employed for computing the DPACS for a series of ellipsoidal droplets (with varying aspect ratio), Chebyshev particles (with different waviness (n) and deformation (ϵ) parameters), healthy red blood cell (RBC) and cells suffering from hereditary disorders (spherocytosis, elliptocytosis and stomatocytosis). The tri-axial ellipsoid form factor (TAEFF), finite cylinder form factor (CFF) and toroid form factor (TFF) models have been used to fit the DPACS spectrum to obtain size and shape information of the PA source. The TAEFF model estimates the shape parameters of the ellipsoidal droplets accurately (error < 5%). It is found that volume estimation is better (error < 10%) for lower order (n = 2, ϵ = ± 0.25) and very higher order (n = 35, 45, ϵ = ± 0.05) Chebyshev particles compared to those of n = 4, 6 and ϵ = ± 0.25. The TAEFF model predicts shape parameters of stomatocyte with volume error ≈15% but it is ≤6% for other cells. The opposite trend is observed for the CFF model. The TFF model is able to estimate the shape parameters efficiently for normal erythrocyte and stomatocyte but gives relatively large errors (>15%) for other deformed RBCs. The inverse problem framework may motivate to develop a PA-based technology to assess single cell morphology.

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Systematic analysis of frequency dependent differential photoacoustic cross-section data for source size estimation

Cited by 5 publications

References 25 publications

Estimation of photoacoustic spectra for normal and pathological red blood cells using a modified Green’s function approach

Estimation of photoacoustic spectra for normal and pathological red blood cells using a modified Green’s function approach

Predicting optoacoustic spectral behaviour of human erythrocytes, stomatocytes and echinocytes using a modified Green’s function method

Characterization of normal and deformed red blood cells using simulated differential photoacoustic cross-section spectral data

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