Non‐invasive Assessment of Skin Microvascular Function in Humans: An Insight Into Methods

Roustit, Matthieu; Cracowski, Jean‐Luc

doi:10.1111/j.1549-8719.2011.00129.x

Cited by 298 publications

(288 citation statements)

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“…Different optical techniques have become available to monitor microvascular blood flow. Among them, the laser Doppler flowmetry (LDF) and the laser speckle contrast imaging (LSCI) offer advantages for a continuous and non invasive monitoring of microvascular blood flow ( [8], [9]). LDF was introduced in the 1970s ( [10]) and is now a commonly used technique that provides an index of perfusion, see an example in Fig.…”

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confidence: 99%

Analysis of Laser Speckle Contrast Images Variability Using a Novel Empirical Mode Decomposition: Comparison of Results With Laser Doppler Flowmetry Signals Variability

Humeau-Heurtier

Ábrahám

2015

IEEE Trans. Med. Imaging

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noise (CEEMDAN). CEEMDAN is suitable for non linear and non stationary data and leads to intrinsic mode functions (IMFs). It is based on the ensemble empirical mode decomposition (EEMD) which relies on empirical mode decomposition (EMD). In our work the average frequencies of LSCI IMFsgiven by CEEMDAN are compared with the ones given by EMD and EEMD. Moreover, LDF signals acquired simultaneously to LSCI data are also processed with CEEMDAN, EMD and EEMD. We show that the average frequencies of IMFs given by CEEMDAN depend on the signal to noise ratio (SNR) used in the computation but, for a given SNR, the average frequencies found for LSCI are close to the ones obtained for LDF. By opposition, EEMD leads to IMFs with frequencies that do not vary much when the SNR level is higher than a threshold. The new CEEMDAN algorithm has the advantage of achieving a complete decomposition with no error in the reconstruction but our study suggests that further work is needed to gain knowledge in the adjustment of the added noise level. CEEMDAN, EMD and EEMD are data-driven methods that can provide a better knowledge of LSCI.Index Terms-Laser speckle contrast imaging, Empirical mode decomposition, Biomedical image processing, Laser Doppler flowmetry, Microvascular blood flow.

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Analysis of Laser Speckle Contrast Images Variability Using a Novel Empirical Mode Decomposition: Comparison of Results With Laser Doppler Flowmetry Signals Variability

Humeau-Heurtier

Ábrahám

2015

IEEE Trans. Med. Imaging

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“…A pele é facilmente acessível [1] e potencialmente representativa [2] para a avaliação dos mecanismos de função e disfunção da microcirculação periférica [3][4][5] em particular quando são usadas tecnologias não invasivas, como a Fluxometria por Laser Doppler (FLD). A FLD está entre as tecnologias mais amplamente utilizadas para este propósito [6] , fornecendo um sinal complexo que pode ser decomposto em componentes com intervalos de frequência característicos, por meio de ferramentas de análise espectrais, tais como a transformada rápida de Fourier, a modelação autorregressiva e a análise de ôndula [7] . A transformada de ôndula permite o isolamento de uma dada estrutura no espaço físico e no espaço de Fourier.…”

Section: Introductionunclassified

“…The skin is easily accessible [1] and potentially representative [2] for the evaluation of peripheral microcirculation function and dysfunction mechanisms [3][4][5] , in particular when noninvasive technologies such as Laser Doppler Flowmetry (LDF) are used. LDF is among the most widely employed technologies for this purpose [6] , providing a complex signal which can be decomposed into components with characteristic frequency ranges by means of spectral analysis tools, such as the fast Fourier transform, autoregressive modelling and wavelet analysis [7] . A wavelet transform allows the isolation of a given structure in the physical space and in the Fourier space.…”

Section: Introductionmentioning

confidence: 99%

The wavelet transform as a tool for the characterization of the vascular response in the human lower limb

Silva¹,

Ferreira²,

Buján³

et al. 2014

BBR

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75 Biomedical and Biopharmaceutical Research J o r n a l d e I n v e s t i g a ç ã o B i o m é d i c a e B i o f a r m a c ê u t i c aThe wavelet transform as a tool for the characterization of the vascular response in the human lower limb AbstractIn recent years, cutaneous microcirculation gained considerable interest for the assessment of microcirculation function and dysfunction mechanisms. Laser Doppler Flowmetry (LDF) is a noninvasive and widely employed technology to study microcirculation. It provides a complex signal that may be decomposed by wavelet analysis into several components at characteristic frequency ranges. These are related to the heart (0.6 Hz to 2 Hz), respiration (0.15 Hz to 0.6 Hz), myogenic activity in the vessel wall (0.052 Hz to 0.15 Hz), sympathetic activity (0.021 Hz to 0.052 Hz) and endothelial (nitric oxide-mediated) activity (0.0095 Hz to 0.021 Hz). A group of 30 healthy (22.3 ± 3.1) years old subjects , giving previously informed consent, tested two perfusion-restricting protocols which allowed us to study the circulatory response in the lower limb: (1) passive leg elevation from the supine position for 10 minutes, (2) inflated cuff occlusion at the ankle level for 3 minutes from the sitting position. The LDF signal was partitioned using a Morlet wavelet model. Data analysis revealed significantly lower components' amplitudes for both protocols during provocation, with consistently lower values for protocol 1 in relation to protocol 2. Significant gender differences were found for protocol 1 but not for protocol 2. These results demonstrate the usefulness of the wavelet analysis to assess each LDF signal component as part of the physiological response to the lower limb microcirculation regulation.

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“…Our goal herein is to report on the potentialities of studies dedicated to the processing of LSCI perfusion data. Linear and nonlinear analyses could be of interest to improve the understanding of LSCI images.Keywords Laser speckle contrast imaging Á Microcirculation Á Signal processing Á Image processing Á Laser Doppler flowmetryIn clinical research, the real-time monitoring of skin microvascular blood perfusion can be performed, among others, with laser Doppler flowmetry (LDF) and laser speckle contrast imaging (LSCI) (see, e.g., [7, 13, 18, 26,43,46]). LDF has been proposed in the 1970's [45] to monitor the microvascular blood perfusion in a small volume of tissue (approximately 1 mm 3 in skin when a 780 nm laser wavelength is used).…”

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“…In clinical research, the real-time monitoring of skin microvascular blood perfusion can be performed, among others, with laser Doppler flowmetry (LDF) and laser speckle contrast imaging (LSCI) (see, e.g., [7,13,18,26,43,46]). LDF has been proposed in the 1970's [45] to monitor the microvascular blood perfusion in a small volume of tissue (approximately 1 mm 3 in skin when a 780 nm laser wavelength is used).…”

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Laser speckle contrast imaging of the skin: interest in processing the perfusion data

Humeau-Heurtier

Buard²,

Mahé

et al. 2011

Med Biol Eng Comput

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Laser speckle contrast imaging (LSCI) is a recent clinical powerful tool to obtain full-field images of microvascular blood perfusion. The technique relies on laser speckle obtained by the interactions between coherent monochromatic radiations and the tissues under study. From these speckle images, contrast values are determined and instantaneous map of the perfusion are computed. LSCI has gained increased attention in the last years and is now additional to laser Doppler flowmetry (LDF). In spite of the growing interest for LSCI in skin clinical research, very few LSCI perfusion data processing have been published from now to extract physiologically-linked indices. By opposition, numerous signal processing works have been dedicated to the processing of LDF signals. The latter works proposed methodological processing procedures to extract information reflecting underlying microvascular mechanisms such as myogenic, neurogenic and endothelial activities. Our goal herein is to report on the potentialities of studies dedicated to the processing of LSCI perfusion data. Linear and nonlinear analyses could be of interest to improve the understanding of LSCI images.Keywords Laser speckle contrast imaging Á Microcirculation Á Signal processing Á Image processing Á Laser Doppler flowmetryIn clinical research, the real-time monitoring of skin microvascular blood perfusion can be performed, among others, with laser Doppler flowmetry (LDF) and laser speckle contrast imaging (LSCI) (see, e.g., [7, 13, 18, 26,43,46]). LDF has been proposed in the 1970's [45] to monitor the microvascular blood perfusion in a small volume of tissue (approximately 1 mm 3 in skin when a 780 nm laser wavelength is used). Since that time, many works have led to the improvements of the technique (see, e.g., [1-6, 10, 29, 38, 39, 47]). LSCI is a more recent technique developed in the mid 1990s. It relies on the speckle phenomenon generated by the interactions between coherent monochromatic radiations and a scattering medium [7]. The first speckle imagers were commercialized very recently and from this time LSCI has been the subject of an increasing number of papers (see, e.g., [7,30,31,40]). LSCI and LDF have found widespread skin vascular application among which we can cite the reperfusion monitoring of skin flaps, the quantification of peripheral vascular diseases, the perfusion monitoring of burns, wounds and foot ulcers. LSCI has the advantage, over LDF, of being a noncontact method and giving a twodimensional image of the perfusion, thus reducing the spatial variability of the measure [42].In the last years, several LDF models and simulations [9, 16, 22-24, 27, 35-37] and many LDF signal processing studies have been published. A number of these signal processing works use wavelets to extract data from the heart rate, respiration, myogenic, neurogenic and endothelial activities (see, e.g., [12, 17,44]

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Non‐invasive Assessment of Skin Microvascular Function in Humans: An Insight Into Methods

Cited by 298 publications

References 153 publications

Analysis of Laser Speckle Contrast Images Variability Using a Novel Empirical Mode Decomposition: Comparison of Results With Laser Doppler Flowmetry Signals Variability

Analysis of Laser Speckle Contrast Images Variability Using a Novel Empirical Mode Decomposition: Comparison of Results With Laser Doppler Flowmetry Signals Variability

The wavelet transform as a tool for the characterization of the vascular response in the human lower limb

Laser speckle contrast imaging of the skin: interest in processing the perfusion data

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