logging in or signing up Biophysics GYoon Clown Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 430 Category: Education License: All Rights Reserved Like it (0) Dislike it (0) Added: January 04, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Spectroscopic Analysis for biological samples : towards in situ sample analysis of body fluids : Spectroscopic Analysis for biological samples : towards in situ sample analysis of body fluids Gilwon Yoon September 27, 2006 Seoul National University of Technology Slide2: Spectra of water, Hb(RBC), albumin, glucose from visible to NIR (water compensated)Slide3: Absorption spectrum of water Slide4: Involved Key Technologies Slide5: Spectroscopic Analysis – Statistical Methods Influence of measurement setup : Transmission or reflection measurement Influence of red blood cell (hemoglobin) in partial least squares regression (PLSR) analysis Independent Component Analysis (ICA) – a method without calibration processSlide6: I. Influence of measurement setup : Transmission or reflection measurementComparison between reflectance and transmittance : Comparison between reflectance and transmittance Jeon, Hwang, Hahn, Yoon (2006), 11:1:014022, Journal of Biomedical Optics Diffuse reflectance between 1100 and 1850 nm (a) SECV with respect to the optimal number of factor, (b) Loading vector of calibration model, (c) Regression vector of calibration model, (d) Prediction of glucose illustrated with the intralipid concentrations of sample solutions. : Diffuse reflectance between 1100 and 1850 nm (a) SECV with respect to the optimal number of factor, (b) Loading vector of calibration model, (c) Regression vector of calibration model, (d) Prediction of glucose illustrated with the intralipid concentrations of sample solutions. Diffuse transmittance with 1 mm thick samples (a) SECV with respect to the optimal number of factor, (b) Loading vector of calibration model, (c) Regression vector of calibration model, and (d) Prediction of glucose concentrations.: Diffuse transmittance with 1 mm thick samples (a) SECV with respect to the optimal number of factor, (b) Loading vector of calibration model, (c) Regression vector of calibration model, and (d) Prediction of glucose concentrations. Slide10: II. Influence of red blood cell (hemoglobin) in partial least squares regression (PLSR) analysis Absorption becomes much stronger towards longer wavelengths Dominance of hemoglobin Interferences among the substances in blood or extracellular fluid Effect of preprocessing methods Biological Samples in the near infrared (1000 – 2500 nm)a) Whole blood spectra of 98 samples and saline spectrum, b) Whole blood spectra are correlated with hemoglobin and glucose concentrations at each wavelength and computed correlations coefficients are shown.: a) Whole blood spectra of 98 samples and saline spectrum, b) Whole blood spectra are correlated with hemoglobin and glucose concentrations at each wavelength and computed correlations coefficients are shown. Slide12: What is a maximally achievable accuracy ? The standard error of glucose prediction was 25.5 mg/dl and the coefficient of variation in prediction was 11.2%. Kim and Yoon (2006), 11: 041128, Journal of Biomedical Optics III. Independent Component Analysis (ICA) – method without calibration process : III. Independent Component Analysis (ICA) – method without calibration process Identification of pure, or individual, absorption spectra of constituent components from the mixture spectra without a priori knowledge of the mixture. This method was tested with a two-component system consisting of aqueous solution of both glucose and sucrose, which exhibit distinct but closely overlapped spectra. ICA combined with principal component analysis was able to identify a spectrum for each component, the correct number of components, and the concentrations of the components in the mixture. This method does not need calibration process. Hahn and Yoon (2006), in print, 45:32, November, Applied Optics Pure, or individual, water-subtracted absorption profiles of Glucose (G) and Sucrose (S) : Pure, or individual, water-subtracted absorption profiles of Glucose (G) and Sucrose (S) 25 measured mid-IR spectra for the mixtures of glucose and sucrose. Water absorption was subtracted to enhance the absorption profile of each component.: 25 measured mid-IR spectra for the mixtures of glucose and sucrose. Water absorption was subtracted to enhance the absorption profile of each component. Extracted pure-component spectra from measured IR spectra of 25. ‘Pure’ and ‘ICA’ represent pure-component absorption spectrum and the ICA-method extracted absorption spectrum respectively. : Extracted pure-component spectra from measured IR spectra of 25. ‘Pure’ and ‘ICA’ represent pure-component absorption spectrum and the ICA-method extracted absorption spectrum respectively. Scatter plot for the reference concentrations and ICs from measured mid-IR spectra : Scatter plot for the reference concentrations and ICs from measured mid-IR spectra Slide18: Measurement geometry or setup – loading factor analysis can provide actual contribution of wavelength in prediction Dominant absorber such as RBC(hemoglobin) and water in near infrared effect substantially. A proper care is needed. A new method that does not require no concentration information and calibration process is introduced. Summary in Spectroscopic analysis You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
Biophysics GYoon Clown Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 430 Category: Education License: All Rights Reserved Like it (0) Dislike it (0) Added: January 04, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Spectroscopic Analysis for biological samples : towards in situ sample analysis of body fluids : Spectroscopic Analysis for biological samples : towards in situ sample analysis of body fluids Gilwon Yoon September 27, 2006 Seoul National University of Technology Slide2: Spectra of water, Hb(RBC), albumin, glucose from visible to NIR (water compensated)Slide3: Absorption spectrum of water Slide4: Involved Key Technologies Slide5: Spectroscopic Analysis – Statistical Methods Influence of measurement setup : Transmission or reflection measurement Influence of red blood cell (hemoglobin) in partial least squares regression (PLSR) analysis Independent Component Analysis (ICA) – a method without calibration processSlide6: I. Influence of measurement setup : Transmission or reflection measurementComparison between reflectance and transmittance : Comparison between reflectance and transmittance Jeon, Hwang, Hahn, Yoon (2006), 11:1:014022, Journal of Biomedical Optics Diffuse reflectance between 1100 and 1850 nm (a) SECV with respect to the optimal number of factor, (b) Loading vector of calibration model, (c) Regression vector of calibration model, (d) Prediction of glucose illustrated with the intralipid concentrations of sample solutions. : Diffuse reflectance between 1100 and 1850 nm (a) SECV with respect to the optimal number of factor, (b) Loading vector of calibration model, (c) Regression vector of calibration model, (d) Prediction of glucose illustrated with the intralipid concentrations of sample solutions. Diffuse transmittance with 1 mm thick samples (a) SECV with respect to the optimal number of factor, (b) Loading vector of calibration model, (c) Regression vector of calibration model, and (d) Prediction of glucose concentrations.: Diffuse transmittance with 1 mm thick samples (a) SECV with respect to the optimal number of factor, (b) Loading vector of calibration model, (c) Regression vector of calibration model, and (d) Prediction of glucose concentrations. Slide10: II. Influence of red blood cell (hemoglobin) in partial least squares regression (PLSR) analysis Absorption becomes much stronger towards longer wavelengths Dominance of hemoglobin Interferences among the substances in blood or extracellular fluid Effect of preprocessing methods Biological Samples in the near infrared (1000 – 2500 nm)a) Whole blood spectra of 98 samples and saline spectrum, b) Whole blood spectra are correlated with hemoglobin and glucose concentrations at each wavelength and computed correlations coefficients are shown.: a) Whole blood spectra of 98 samples and saline spectrum, b) Whole blood spectra are correlated with hemoglobin and glucose concentrations at each wavelength and computed correlations coefficients are shown. Slide12: What is a maximally achievable accuracy ? The standard error of glucose prediction was 25.5 mg/dl and the coefficient of variation in prediction was 11.2%. Kim and Yoon (2006), 11: 041128, Journal of Biomedical Optics III. Independent Component Analysis (ICA) – method without calibration process : III. Independent Component Analysis (ICA) – method without calibration process Identification of pure, or individual, absorption spectra of constituent components from the mixture spectra without a priori knowledge of the mixture. This method was tested with a two-component system consisting of aqueous solution of both glucose and sucrose, which exhibit distinct but closely overlapped spectra. ICA combined with principal component analysis was able to identify a spectrum for each component, the correct number of components, and the concentrations of the components in the mixture. This method does not need calibration process. Hahn and Yoon (2006), in print, 45:32, November, Applied Optics Pure, or individual, water-subtracted absorption profiles of Glucose (G) and Sucrose (S) : Pure, or individual, water-subtracted absorption profiles of Glucose (G) and Sucrose (S) 25 measured mid-IR spectra for the mixtures of glucose and sucrose. Water absorption was subtracted to enhance the absorption profile of each component.: 25 measured mid-IR spectra for the mixtures of glucose and sucrose. Water absorption was subtracted to enhance the absorption profile of each component. Extracted pure-component spectra from measured IR spectra of 25. ‘Pure’ and ‘ICA’ represent pure-component absorption spectrum and the ICA-method extracted absorption spectrum respectively. : Extracted pure-component spectra from measured IR spectra of 25. ‘Pure’ and ‘ICA’ represent pure-component absorption spectrum and the ICA-method extracted absorption spectrum respectively. Scatter plot for the reference concentrations and ICs from measured mid-IR spectra : Scatter plot for the reference concentrations and ICs from measured mid-IR spectra Slide18: Measurement geometry or setup – loading factor analysis can provide actual contribution of wavelength in prediction Dominant absorber such as RBC(hemoglobin) and water in near infrared effect substantially. A proper care is needed. A new method that does not require no concentration information and calibration process is introduced. Summary in Spectroscopic analysis