Scattering and Absorption Effects in the Determination of Glucose in Whole Blood by Near-Infrared Spectroscopy

Optical properties of whole bovine blood are examined under conditions of different glucose loadings. A strong dependency is established between the scattering properties of the whole blood matrix and the concentration of glucose. This dependency is explained in terms of variations in the refractive...

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Bibliographic Details
Published in:Analytical chemistry (Washington) 2005-07, Vol.77 (14), p.4587-4594
Main Authors: Amerov, Airat K, Chen, Jun, Small, Gary W, Arnold, Mark A
Format: Article
Language:English
Subjects:
Analytical chemistry
Animals
Blood
Calibration
Cattle - blood
Chemistry
Exact sciences and technology
Glucose
Glucose - analysis
Scattering
Sorption
Spectrometric and optical methods
Spectrophotometry, Infrared - methods
Spectrum analysis
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Summary:Optical properties of whole bovine blood are examined under conditions of different glucose loadings. A strong dependency is established between the scattering properties of the whole blood matrix and the concentration of glucose. This dependency is explained in terms of variations in the refractive index mismatch between the scattering bodies (predominately red blood cells) and the surrounding plasma. Measurements in the presence of a well-known glucose transport inhibitor indicate that variations in refractive index mismatch are related to the penetration of glucose into the red blood cells and demonstrate that increased scattering involves the uptake of glucose by red blood cells. Finally, multivariate calibration models are presented for the measurement of glucose in a whole blood matrix. These models are based on near-infrared spectral data collected from 80 different samples prepared from a single whole blood matrix. Calibration studies are performed over the combination, first-overtone, and short-wavelength spectral regions. The best calibration model is generated from combination region spectra, providing a standard error of prediction (SEP) of less than 1 mM over the concentration range of 3−30 mM. The model based on the first-overtone region is slightly degraded but still provides acceptable performance (SEP = 1.20 mM). The model based on the short-wavelength region is further degraded (SEP = 2.53 mM). To rationalize these results, an analysis of the selectivity of the calibration models is performed by computing the glucose net analyte signal. It is established that the models based on the combination and first-overtone regions are dominated by glucose absorption information, while the model computed from the short-wavelength region is based primarily on scattering information. This result provides evidence that absorption information is needed in order to obtain a glucose calibration model with acceptable performance.
ISSN:0003-2700
1520-6882
DOI:10.1021/ac0504161