Wavelet prism decomposition analysis applied to CARS spectroscopy: a tool for accurate and quantitative extraction of resonant vibrational responses

Kan, Yelena; Lensu, Lasse; Hehl, Gregor; Volkmer, Andreas; Vartiainen, Erik M.

doi:10.1364/oe.24.011905

Cited by 14 publications

(28 citation statements)

References 30 publications

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“…We model CARS spectral measurements with an additive error model given as where y k denotes a measurement that has been discretized with spectral sampling resolution h > 0 at a wavenumber location ν k = kh with , f (ν k ; p , θ ) is the CARS spectrum model with parameter p controlling the baseline and parameters θ for the Voigt line shape, and with measurement error with known variance. For the spectrum, we use a parameter-wise separable model where p is the interpolated discrete wavelet transform (DWT) detail level, ε m (ν; p ) is the modulating error function, and S (ν; θ ) is the error-corrected CARS signal, similar to the representation used in ref ( 22 ). The signal S can further be represented as where the exponential part corresponds to the non-Raman part with A J practically constant (see ref ( 22 ) for details), is the Hilbert transform, and where * denotes convolution.…”

Section: Methodsmentioning

confidence: 99%

“…For the spectrum, we use a parameter-wise separable model where p is the interpolated discrete wavelet transform (DWT) detail level, ε m (ν; p ) is the modulating error function, and S (ν; θ ) is the error-corrected CARS signal, similar to the representation used in ref ( 22 ). The signal S can further be represented as where the exponential part corresponds to the non-Raman part with A J practically constant (see ref ( 22 ) for details), is the Hilbert transform, and where * denotes convolution. N stands for the number of line shapes, with each line shape having θ n ≔ ( a n , ν n , σ n , γ n ) T parameters standing for the amplitude, location, scale of the Gaussian shape, and scale of the Lorentzian shape, respectively.…”

Section: Methodsmentioning

confidence: 99%

“…Instead of the wavelet prism method, 22 we model the modulating error function as where p ∈ [1, J ], and β = p – ⌊ p ⌋, i.e., as an interpolation between the discrete wavelet reconstruction levels D j to have a continuous model for the background in contrast to the wavelet prism method where only the discrete wavelet reconstruction levels are used. With the above, we can have an unnormalized posterior formulated as where is the vector of observations given via eq 1 , is the parameter vector ( θ 1 , ..., θ N ) T for the N Voigt peaks, represents the likelihood distribution of the forward model, and π 0 ( p , θ ) denotes prior distributions for some or all of the model parameters p and θ .…”

Section: Methodsmentioning

confidence: 99%

“…Recently, a procedure based on the wavelet prism decomposition algorithm was proposed to address this issue. 22 …”

Section: Introductionmentioning

confidence: 99%

“…Using the Hilbert transform, we construct the modulus of the resonant part of the CARS spectrum. A nonresonant part, estimated from the data, 22 is added to obtain an error-free CARS spectrum, which is finally modulated with a slowly varying error function. Next, we describe the numerical algorithms used for statistical inference and line narrowing, along with our Bayesian prior distributions.…”

Section: Introductionmentioning

confidence: 99%

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Bayesian Quantification for Coherent Anti-Stokes Raman Scattering Spectroscopy

et al. 2020

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We propose a Bayesian statistical model for analyzing coherent anti-Stokes Raman scattering (CARS) spectra. Our quantitative analysis includes statistical estimation of constituent line-shape parameters, the underlying Raman signal, the error-corrected CARS spectrum, and the measured CARS spectrum. As such, this work enables extensive uncertainty quantification in the context of CARS spectroscopy. Furthermore, we present an unsupervised method for improving spectral resolution of Raman-like spectra requiring little to no a priori information. Finally, the recently proposed wavelet prism method for correcting the experimental artifacts in CARS is enhanced by using interpolation techniques for wavelets. The method is validated using CARS spectra of adenosine mono-, di-, and triphosphate in water, as well as equimolar aqueous solutions of d -fructose, d -glucose, and their disaccharide combination sucrose.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

“…Recently, a procedure based on the wavelet prism decomposition algorithm was proposed to address this issue. 22 …”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Bayesian Quantification for Coherent Anti-Stokes Raman Scattering Spectroscopy

et al. 2020

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Quantitative coherent Raman scattering microscopies: new tools for the material and life sciences

Volkmer

2016

European Microscopy Congress 2016: Proceedings

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Unlike optical microscopies that are based on fluorescence detection, Raman‐based micro‐spectroscopies provide vibrational signatures that themselves represent quantitative measures of the sample's molecular composition and structures, which for example can be successfully exploited as an intrinsic vibrational contrast of endogenous biomolecular species for label‐free tumour diagnostic imaging [1]. In particular, by exploiting the coherent driving and detection of Raman modes in coherent anti‐Stokes Raman scattering (CARS) and stimulated Raman scattering (SRS), coherent Raman scattering (CRS) microscopy allows the point‐by‐point chemical mapping of molecular compounds, which is often difficult to attain by conventional fluorescence and incoherent vibrational microscopy techniques. Here, we will review on two CRS modalities that provide quantitative molecular information [2]: (i) high‐speed stimulated Raman loss (SRL) imaging at video‐rates and (ii) hyperspectral CARS imaging that provides access to the full wealth of chemical and physical structure information of an a priori unknown molecular sample. We will discuss their underlying principles, their state‐of‐the‐art experimental realizations, and demonstrate exemplifying applications for the label‐free and noninvasive 3D visualization of chemical composition as well as of molecular structure properties of (bio)molecular components in heterogeneous and complex materials, ranging from polymers to living cells. Particular emphasis will be given to the combination of coherent Raman scattering spectroscopy with optical microscopy, which has emerged as a highly sensitive and chemically selective tool for the extraction of quantitative molecular structure information from purely imaginary hyperspectral data cubes of the sample's complex third‐order nonlinear susceptibility, χ (3) (ν,x,y,z), as obtained by fast hyperspectral CARS imaging in conjunction with spectral phase retrieval algorithms. We will introduce a novel concept based on the wavelet prism decomposition and the maximum entropy method (MEM) for the fast and robust reconstruction of the pure vibrational response of the molecular sample inside a sub‐femtoliter probe volume in the presence of experimental artefacts, which may obstruct the accurate phase retrieval from the experimental normalized CARS pixel spectra [3]. Furthermore, we will present exemplifying applications (see Fig. 1) for the quantitative 3D mapping of chemical composition in living cells, the intracellular chemical structure analysis of biologically relevant lipids, and the physical 3D structure analysis in polymers.

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